kom (2025) 0180 - Ingen titel

Europaudvalget 2025
KOM (2025) 0180
Offentligt

EUROPEAN

COMMISSION

Brussels, 26.5.2025

SWD(2025) 96 final/2

CORRIGENDUM

This document replaces SWD(2025) 96 final of 24.4.2025

Insertion of the cross-reference to the COM(2025) 180 final

The text shall read as follows:

Roadworthiness package

COMMISSION STAFF WORKING DOCUMENT

IMPACT ASSESSMENT REPORT

on the revision of the Directives of the Roadworthiness package

Accompanying the documents

Proposal for a Directive of the European Parliament and of the Council amending

Directive 2014/45/EU on periodic roadworthiness tests for motor vehicles and their

trailers, and amending Directive 2014/47/EU on the technical roadside inspection of the

roadworthiness of commercial vehicles circulating in the Union

Proposal for a Directive of the European Parliament and of the Council on the

registration documents for vehicles and vehicle registration data recorded in national

vehicle registers, and repealing Council Directive 1999/37/EC

{COM(2025) 179 final} - {SEC(2025) 119 final} - {SWD(2025) 97 final} -

{SWD(2025) 98 final} - {SWD(2025) 99 final} - {COM(2025) 180 final}

•

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Table of contents

INTRODUCTION: POLITICAL AND LEGAL CONTEXT ................................................. 1

PROBLEM DEFINITION ....................................................................................................... 7

2.1.

2.2.

2.3.

3.1.

3.2.

3.3.

4.1.

4.2.

5.1.

5.2.

6.1.

6.2.

6.3.

7.1.

7.2.

7.3.

7.4.

8.1.

8.2.

8.3.

What is/are the problems?............................................................................................. 7

What are the problem drivers? .................................................................................... 14

How likely is the problem to persist? ......................................................................... 19

Legal basis .................................................................................................................. 21

Subsidiarity: Necessity of EU action .......................................................................... 21

Subsidiarity: Added value of EU action ..................................................................... 21

General objectives ...................................................................................................... 22

Specific objectives ...................................................................................................... 22

What is the baseline from which options are assessed? .............................................. 23

Description of the policy options ................................................................................ 26

Economic impacts ....................................................................................................... 31

Social impacts ............................................................................................................. 56

Environmental impacts ............................................................................................... 59

Effectiveness ............................................................................................................... 62

Efficiency.................................................................................................................... 63

Coherence ................................................................................................................... 65

Subsidiarity and proportionality ................................................................................. 66

Identification of the preferred policy options and stakeholder views ......................... 70

REFIT (simplification and improved efficiency) ....................................................... 72

Application of the ‘one in, one out’ approach ............................................................ 73

WHY SHOULD THE EU ACT?........................................................................................... 21

OBJECTIVES: WHAT IS TO BE ACHIEVED? ................................................................. 22

WHAT ARE THE AVAILABLE POLICY OPTIONS? ....................................................... 23

WHAT ARE THE IMPACTS OF THE POLICY OPTIONS? ............................................. 31

HOW DO THE OPTIONS COMPARE? .............................................................................. 62

PREFERRED OPTION ......................................................................................................... 67

HOW WILL ACTUAL IMPACTS BE MONITORED AND EVALUATED? .................... 74

ANNEX 1: PROCEDURAL INFORMATION ............................................................................. 75

ANNEX 2: STAKEHOLDER CONSULTATION (SYNOPSIS REPORT) ................................. 80

ANNEX 3: WHO IS AFFECTED AND HOW? .......................................................................... 100

ANNEX 4: ANALYTICAL METHODS ..................................................................................... 108

ANNEX 5: COMPETITIVENESS CHECK ................................................................................ 262

ANNEX 6: BACKGROUND ON ROADWORTHINESS LEGISLATION AND PTI

ORGANISATION IN MEMBER STATES................................................................................. 265

ANNEX 7: DETAILED DESCRIPTION OF THE RETAINED POLICY MEASURES ........... 271

ANNEX 8: DISCARDED POLICY MEASURES ...................................................................... 287

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ANNEX 9: COMPARISON OF POLICY OPTIONS IN TERMS OF MEETING THE

OBJECTIVES .............................................................................................................................. 290

ANNEX 10: SME TEST .............................................................................................................. 295

ANNEX 11: LINKS BETWEEN THE CONCLUSIONS OF THE EX-POST EVALUATION

AND THE IMPACT ASSESSMENT .......................................................................................... 298

ANNEX 12: IMPACTS ON FUNDAMENTAL RIGHTS .......................................................... 300

ANNEX 13: IMPACTS ON THE FUNCTIONING OF THE INTERNAL MARKET AND

COMPETITION ........................................................................................................................... 302

ANNEX 14: COHERENCE, SUBSIDIARITY AND PROPORTIONALITY (DETAILED

ANALYSIS) ................................................................................................................................. 304

ANNEX 15: MONITORING ....................................................................................................... 308

ANNEX 16: SYNERGIES WITH OTHER POLICY INSTRUMENTS ..................................... 310

ANNEX 17: EVALUATION REPORT (SEPARATE DOCUMENT) ....................................... 313

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Glossary

Term or acronym

ADAS

Meaning or definition

Advanced Driver Assistance Systems refer to systems that support the

driver in their primary driving task. These systems can inform or warn

the driver, but also take over (part of) vehicle control.

CARE is a Community database on road crashes resulting in death or

injury (no statistics on damage-only crashes).

International Motor Vehicle Inspection Committee, worldwide

association of authorities and authorised companies active in the field

of vehicle compliance

Carbon monoxide: colourless odourless very toxic gas that is formed

as a product of the incomplete combustion of carbon or a carbon

compound. The greatest sources of CO to outdoor air are vehicles or

machinery that burn fossil fuels.

Certificate of Conformity: a statement by a vehicle manufacturer that

the vehicle conforms to EU type-approval requirements.

Diesel Particle Filter, a component designed to remove diesel

particulate matter or soot from the exhaust gas of a diesel engine.

European Environment Agency

End-of-Life Vehicles

Association of European Vehicle and Driver Registration Authorities

European car and driving licence information system

Electric vehicle, including battery electric, hybrid electric, and fuel cell

electric vehicles

General Safety Regulation (EU) 2019/2144: type-approval

requirements to ensure the general safety of vehicles and the protection

of vulnerable road users

CARE

CITA

CoC

DPF

EEA

ELV

EReg

EUCARIS

GSR

III

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HDV

Heavy-duty vehicle, vehicles above 3.5t maximum permissible laden

mass, including trucks and buses/coaches

Heavy goods vehicle, truck

Light-duty vehicle (i.e., up to 3.5t maximum mass), including cars and

vans (light commercial vehicles, LCVs)

Nitrogen dioxide, nitrogen oxides, including NO and NO

Ammonia, NH3 contributes to acid deposition and eutrophication,

which in turn, can lead to potential changes occurring in soil and water

quality.

A vehicle system that can generate on-board diagnostics. It collects

information from the network of sensors inside the vehicle, which the

OBD can use to regulate car systems or alert the user to problems. A

technician can plug into the OBD port to collect vehicle data and

diagnose problems. Recent models can communicate diagnostic

information over the air.

On-Board Monitoring means a system on board a vehicle that is

capable of detecting and communicating either emission exceedances

or when a vehicle is in zero emission mode, via the OBD port and over

the air.

A new emission testing method used to detect high-emitting vehicles.

Also called mobile remote sensing where a chasing vehicle follows the

target vehicle, typically a truck.

Particulate matter (with a diameter smaller than 2.5 micrometres

(<2,5 µm)): the emission limits for mass of particulate matter are

regulated by type-approval legislation for light (Euro 5 and Euro 6) as

well as heavy-duty vehicles (Euro VI)

Particle number, another measure of air pollution, the emission limits

for PN were introduced in the type-approval regulations from Euro 5b

light vehicles (first registered from 1 January 2013) and from Euro VI

HDVs (first registered from 1 January 2014)

Periodic technical inspection (Directive 2014/45/EU on periodic

roadworthiness tests for motor vehicles and their trailers)

HGV

LDV

, NO

OBD

OBM

Plume chasing

(2.5)

PTI (Directive)

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PTI centre

A PTI station, an authorised workshop or larger inspection centre with

one or more PTI lanes

Test lanes along which the vehicle advances during the various stages

of PTI

A method that measures the various components of exhaust emissions

of vehicles that pass by the remote sensing device using a light beam

and detectors

Roadside inspection (Directive 2014/47/EU on the technical roadside

inspection of the roadworthiness of commercial vehicles circulating in

the Union)

Roadworthiness package: Directive 2014/45/EU,

2014/46/EU amending Directive 1999/37/EC, and

2014/47/EU

Directive

PTI lane

Remote sensing

RSI (Directive)

RWP

SCR

Selective Catalytic Reduction is a technology that reduces nitrogen

oxides (NOx) from exhaust gases of diesel engines. It converts NOx

into nitrogen and water vapour and improves fuel economy and the

performance of diesel engines.

SDG (Regulation) Single Digital Gateway (Regulation (EU) 2018/1724) establishing a

single digital gateway to facilitate online access to information,

administrative procedures, and assistance services that citizens and

businesses may need in another EU country

UN SDG

VRD (Directive)

United Nations Sustainable Development Goals

Vehicle registration documents (Directive 1999/37/EC, as amended by

Directive 2014/46/EU)

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NTRODUCTION

: P

OLITICAL AND LEGAL CONTEXT

This Impact Assessment accompanies legislative proposals for the revision of three Directives, collectively

called the Roadworthiness Package (hereinafter the “RWP”):

•

Directive 2014/45/EU on periodic roadworthiness tests for motor vehicles and their trailers (hereinafter

the "Periodic Technical Inspection” or “PTI” Directive)

;

•

Council Directive 1999/37/EC on the registration documents for vehicles as amended by Directive

2014/46/EU (hereinafter the "Vehicle Registration Documents” or “VRD” Directive)

;

•

Directive 2014/47/EU on the technical roadside inspection of the roadworthiness of commercial vehicles

(hereinafter the “Technical Roadside Inspection” or “RSI” Directive)

Road transport plays a vital role in connecting businesses and consumers across the EU, facilitating trade,

and supporting economic growth and employment. It facilitates mobility of people and supports many

industries, such as manufacturing, construction and retail, by providing the means for the transport of goods.

It also plays a critical role in emergency response. In 2021, road freight transport represented 54.3% (1,863

billion tonne-kilometres) of all the goods transported within the EU and was responsible for 87% (4,174

billion passenger-kilometres) of the total passenger transport activity

. The road transport sector employs

more than 5 million people in the EU, of which 3.3 million work in freight and 1.8 million in passenger

transport. At the same time, it is a source of certain negative impacts that are addressed by various EU and

national transport policies, among which the Roadworthiness Package is a key building block.

Safe vehicles are part of the so-called “Safe System approach”, as presented in the EU Road Safety

Policy Framework 2021-2030 – Next steps towards “Vision Zero” (

). In this road safety strategy,

the Commission proposed new interim targets of reducing the number of road deaths by 50% between

2020 and 2030 as well as reducing the number of serious injuries by 50% over the same period. The

UN Global Plan for the Decade of Action (

) released in October 2021, also applying the “Safe

System approach”, promotes the same reduction targets already in place at EU level.

The Safe System approach considers death and serious injury in road collisions as being largely

preventable, while acknowledging that collisions will continue to occur. It takes as a point of

departure the fact that people make mistakes and aims to ensure that such mistakes do not cause

fatalities or serious injuries by acting on five pillars: safe roads and roadsides, safe speeds, safe road

users, safe vehicles, and fast and effective post-crash care, which all contribute to reducing the impact

of crashes. The Roadworthiness Package focuses on the safe vehicle part of this system.

In its Sustainable and Smart Mobility Strategy (

) of 2020, the Commission reiterated the target of

zero fatalities in all modes of transport by 2050 and announced the revision of the roadworthiness

legislative framework, to ensure the lifetime compliance of vehicles with emission and safety

standards, under Flagship 1 “Boosting the uptake of zero-emission vehicles, renewable & low-carbon

fuels and related infrastructure”. In October 2021, the European Parliament adopted a resolution on

the EU Road Safety Policy Framework 2021-2030 (

), calling on the Commission to consider, among

https://eur-lex.europa.eu/eli/dir/2014/45/oj

https://eur-lex.europa.eu/legal-content/EN/TXT/?uri=CELEX%3A01999L0037-20220324

https://eur-lex.europa.eu/eli/dir/2014/47/oj

Statistical pocketbook 2023 (europa.eu)

( ) SWD(2019) 283 final

(

)

Decade of Action - United Nations Sustainable Development

(

) COM(2020) 789 final

(

) P9_TA(2021)0407

https://www.europarl.europa.eu/doceo/document/TA-9-2021-0407_EN.pdf

kom (2025) 0180 - Ingen titel

others, tightening the roadworthiness test regime and to adapt it to the technical progress in vehicle

safety features.

Road crashes

represent one of the most significant negative impacts of road transport. The external cost of

crashes represents almost EUR 250 billion per year, i.e., roughly 2% of GDP

. There were around 20,600

fatal crashes in the EU in 2022, a 3% increase on 2021 as traffic levels recovered after the pandemic. This

represents however 2,200 fewer fatalities (-10%) compared with the pre-pandemic year 2019 (see Figure

1). The EU and UN target is to halve the number of road deaths by 2030

. The main causes of road crashes

are speeding, alcohol/drugs, distracted driving, and various driver errors (such as errors of interpretation or

fatigue). Other causes include the inadequate state or design of infrastructure (slippery surface, insufficient

markings, poor maintenance), and vehicle defects. In the EU, thanks to gradually improving vehicle

technology through EU type-approval rules and a well-developed system of technical inspections to

ascertain vehicle safety over the entire lifetime, the share of vehicle defects among the causes of road crashes

is now limited to just a few percent

. However, this also means that avoidable crashes caused by vehicle

defects are still taking place. The Safe System approach requires acting on all these fronts, recognising that

the parts of the entire system – including users, vehicles, infrastructure and emergency response – work

together as an entity

Figure 1: Road fatalities in the EU (2001-2022 and the EU 2030 target)

Air pollutant emissions

from road transport have been decreasing ever since the introduction of the first

Euro emission standard over 30 years ago. Although subsequent emission standards gradually reduced the

limits and extended the scope of air pollutants measured, real-life emissions were significantly above the

type-approval limits until recently (i.e. when RDE limits were introduced)

. Recent remote sensing

campaigns indicate that even some of the newest vehicles exceed legal emission limits

. According to the

In this document we use the term ‘road crash’ and not ‘road accident’. The word

accident

implies that a car crash

happened through the fault of nobody. On the other hand, the word

crash

indicates that someone caused the car wreck to

happen, or that someone is at fault. The reality is that it is very rare for a car crash to be just an accident, while many

studies point out the fact that most causes of the accidents are attributable to human error.

COM(2020) 789 final,

https://eur-lex.europa.eu/legal-content/EN/TXT/PDF/?uri=CELEX:52020SC0331.

1.87%

based on CE Delft et al. (2020), Handbook on the external costs of transport – Version 2019 – 1.1, Publications Office,

https://data.europa.eu/doi/10.2832/51388

https://transport.ec.europa.eu/news-events/news/road-safety-eu-fatalities-below-pre-pandemic-levels-progress-

remains-too-slow-2023-02-21_en

See Section 2.1.1.

European Commission (2020), Directorate-General for Mobility and Transport, Next steps towards ‘Vision Zero’ –

EU road safety policy framework 2021-2030, Publications Office, 2020,

https://data.europa.eu/doi/10.2832/391271

Real-driving emission (RDE) limits were introduced following the “diesel-gate” scandal:

https://single-market-

economy.ec.europa.eu/sectors/automotive-industry/environmental-protection/emissions-automotive-sector_en

https://cares-project.eu/cares-open-letters/

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European Environment Agency (EEA), despite some improvement, air pollution remains the largest

environmental health risk in Europe. Exposure to fine particulate matter (PM) and nitrogen dioxide (NO

)

levels caused just under 300,000 premature deaths in 2020. Road transport is the principal source of nitrogen

oxides, responsible for 35.5% of emissions in 2022, and accounts for a significant share of PM emissions

(8.1% of the PM

2.5

and 9.5% of the PM

emissions)

. In 2022, the Commission proposed

to revise the

Ambient Air Quality Directives

which aims to put the EU on a path to achieve zero pollution for air at the

latest by 2050 and sets interim 2030 ambient air quality standards aligned more closely with the updated air

quality guidelines issued by the World Health Organization (WHO)

for key air pollutants, requiring

enhanced measures to reduce emissions at source.

For

noise emissions,

EEA indicates that road transport plays the most significant role

, with 70% of the EU

population living in urban areas and 25% of the population living outside urban areas being exposed to road

traffic noise with an equivalent sound pressure level exceeding 55 dB(A) during daytime

21,22

. While a large

part of this can be attributed to the volume of traffic and a few other factors, noise emission levels of

individual vehicles play a key role, too. The permissible sound level of various road vehicles is regulated

by UNECE and EU type-approval legislation

. However, here again, regulatory limits are not necessarily

respected in real life

Legal context

To address the safety- and nuisance-related defects of vehicles, roadworthiness testing has been in place in

Europe for decades and subject to gradual harmonisation in the Union, with the first set of common rules

adopted in 1976

and last revised in 2014 as part of the RWP. Consecutive revisions gradually extended

the scope of vehicles to be tested, as well as the scope of harmonised rules, including requirements on

roadside inspections and vehicle registration documents to improve enforcement. They further specified

and updated the required test methods, procedures and related documents to reflect technological progress

Today, the

PTI Directive

requires that Member States carry out periodic technical inspections (PTI) on

most of the vehicles registered in their territory. This covers cars (M1), vans (N1), lorries (N2-N3), buses

(M2-M3), as well as heavy trailers (O3-O4) and high-speed tractors (T with design speed over 40 km/h). It

also covers heavy motorcycles, including tricycles and quadricycles (L3e, L4e, L5e and L7e), equipped

with a combustion engine above 125 cm

, with certain possibilities for exemptions. The Directive sets out

the minimum content

and frequency of testing for each vehicle category, except for motorcycles, where

National air pollutant emissions data viewer 2005-2022 | European Environment Agency's home page,

EEA (2024),

Air Pollution in Europe; 2024 reporting status,

https://www.eea.europa.eu/publications/national-emission-reduction-

commitments-directive-2024

COM/2022/542 final

Directive 2004/107/EC relating to arsenic, cadmium, mercury, nickel and polycyclic aromatic hydrocarbons in ambient

air; Directive 2008/50/EC on ambient air quality and cleaner air for Europe.

WHO (2021)

WHO Global Air Quality Guidelines.

https://www.eea.europa.eu/en/topics/in-depth/noise

During night-time, 49% of the EU population living in urban areas and 17% of the population living outside urban

areas are exposed to road traffic noise with an equivalent sound pressure level exceeding 50 dB(A).

Noise — European Environment Agency (europa.eu)

https://environment.ec.europa.eu/topics/noise/noise-pollution-main-sources_en

The UK and France have experimented with roadside trials to monitor excessive vehicle noise: Décret n° 2022-1;

https://www.gov.uk/government/publications/roadside-vehicle-noise-measurement-study-enforcement-and-technology

Council Directive 77/143/EEC of 29 December 1976 on the approximation of the laws of the Member States relating

to roadworthiness tests for motor vehicles and their trailers,

OJ L 47, 18.2.1977, p. 47–51

The evolution of the PTI legislation is illustrated in Annex 6.

(0) Identification of the vehicle; (1) Braking equipment; (2) Steering; (3) Visibility; (4) Lighting equipment and parts

of the electrical system; (5) Axles, wheels, tyres, suspension; (6) Chassis and chassis attachments; (7) Other equipment;

(8) Nuisance; (9) Supplementary tests for passenger-carrying vehicles of categories M2 and M3.

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Member States have a larger room for manoeuvre. Any deficiency found on a vehicle must be categorised

as minor, major or dangerous, with the latter two leading to the suspension of the vehicle’s authorisation to

be used in road traffic. The Directive also sets out minimum requirements as regards the independence of

testing centres and training of inspectors, testing equipment, and the content of the roadworthiness (PTI)

certificate. The validity of that certificate, as well as any other proof of test, must be recognised by Member

States for the purposes of free circulation and re-registration of a vehicle already registered in another

Member State.

The

RSI Directive

complements the PTI Directive by requiring Member States to carry out roadside

inspections (RSI) on heavy commercial vehicles, i.e., buses, lorries, and their trailers (above 3.5t), with a

target of 5% of the fleet each year. Those inspections must include an initial roadside inspection and, if

deemed necessary by the inspector, a more detailed technical roadside inspection. The scope of those

detailed inspections are the items tested at PTI and it may also include the inspection of cargo securing.

When a major or dangerous deficiency is found during a RSI, the Member State where the inspection took

place must notify the Member State of registration, in order to enforce the repair of the vehicle that has been

suspended from traffic.

Vehicle registration itself is a national competence. The

VRD Directive

specifies that Member States must

issue registration certificates for vehicles that are subject to registration under their national legislation. It

requires that those certificates be issued in either paper or smart card format. The certificates must contain

a minimum set of mandatory data elements, may contain certain optional data elements, and must be

recognised among Member States for the purpose of re-registration. The Directive requires certain vehicle

data to be registered electronically, including the suspension from traffic following a failed PTI, and the

cancellation of registration where a vehicle has been treated as an end-of-life vehicle in accordance with

Directive 2000/53/EC

The most recent act adopted by the Commission in the area of roadworthiness testing is a recommendation

on particle number (PN) measurement at the periodic technical inspection of diesel vehicles

. Although

non-binding, the recommendation aims at harmonising the methods of such measurements and the

corresponding pass/fail limit instead of the introduction of various methods at national and regional level.

Similar Commission recommendations on the assessment of defects during roadworthiness testing have

served as basis for the minimum requirements concerning the contents and recommended methods of

testing under the current PTI Directive

Political context

Although the PTI and RSI Directives were marginally amended through delegated acts

, to align them with

updated vehicle categories in type-approval legislation

and introduce the testing of eCall

at PTI, the main

rules remained the same since 2014. Due to rapid technological progress, some of these rules are however

already outdated. For this reason, the Sustainable and Smart Mobility Strategy

called for adjustments to

the roadworthiness legislative framework to ensure lifetime compliance of vehicles with emission and

https://eur-lex.europa.eu/eli/dir/2000/53/oj

https://eur-lex.europa.eu/eli/reco/2023/688/oj

https://eur-lex.europa.eu/eli/reco/2010/378/oj

https://eur-lex.europa.eu/eli/dir_del/2021/1717/oj

and

https://eur-lex.europa.eu/eli/dir_del/2021/1716/oj

Regulation (EU) No 168/2013; Regulation (EU) No 167/2013; Regulation (EU) No 2018/858

https://eur-lex.europa.eu/eli/reg/2015/758/oj

COM(2020) 789 final

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safety standards, thereby contributing to the EU Road Safety policy framework 2021 - 2030

and

supporting the European Green Deal’s objectives.

Roadworthiness inspections of vehicles are fundamental to road safety and to ensure the environmental

performance of vehicles during their lifetime. As a result of stricter safety and emission legislation, vehicles

in the EU have become technically ever more complex. To keep pace with this trend, certain adaptations to

how vehicles are inspected are necessary. In addition, enhanced and more effective EU-wide exchange of

roadworthiness-relevant vehicle data would help better enforcement of the rules, improving the functioning

of the internal market and protecting citizens from fraudulent malpractices, such as odometer tampering

During the last five years, the European Parliament published a number of related reports and studies,

including a resolution on the implementation of the Roadworthiness package in general

and on the specific

issue of odometer fraud

. In these documents, the Parliament pointed at the insufficient decrease in road

fatalities and a massive divergence between Member States, highlighting the importance of independent

inspections in the wake of emission scandal, the issue of odometer tampering, especially cross-border, as

well as the need for further harmonisation of test methods and updates required by the introduction of

advanced driver assistance systems and automated driving features. The Parliament called on the

Commission to consider tightening the test regime by introducing the obligation of additional checks after

reaching a specified mileage for cars used as a taxi or ambulance and for vans, ending the exemption of

motorcycles from PTI and introducing mandatory testing of powered two- and three-wheelers with an

engine below 125 cm

and light trailers. In the resolution on the specific issue of odometer fraud, the

Parliament drew the attention to the economic and legal significance of odometer fraud in the EU and

requested the Commission to submit a proposal for a legislative framework to prevent odometer fraud.

Synergies with other EU policy instruments

Roadworthiness testing relies on the technical specifications of the vehicles that are harmonised at EU level

and beyond (UNECE

). Vehicle registration remains a national competence, although it relies on the

Certificate of Conformity also defined in type-approval legislation

. The most recent and relevant safety-

and emissions-related type-approval regulations are the

General Safety Regulation

(GSR)

and the

Euro

7 Regulation (EU) 2024/1257

. The GSR requires that, from July 2022, new types of motor vehicles are

equipped with advanced driver assistant systems aimed at reducing the number of fatalities and serious

injuries; these will also be used in automated vehicles. At the time of preparing this impact assessment, it

was expected that the co-legislators would adopt the

Euro 7 standards

replacing existing emission rules

http://eur-lex.europa.eu/resource.html?uri=cellar%3A0e8b694e-59b5-11e8-ab41-

01aa75ed71a1.0003.02/DOC_2&format=PDF

An odometer is an instrument measuring the distance travelled by a vehicle. Odometer fraud or tampering is the

disconnection, resetting or alteration of a vehicle’s odometer with the intention to change the number of kilometres

indicated. Both digital and analogue odometers can be tampered with and changed. Many newer vehicles have digital

control units or computers that may allow for the odometer to be replaced or re-programmed using fraudulent software.

European Parliament resolution of 27 April 2021 on the implementation report on the road safety aspects of the

Roadworthiness Package (2019/2205(INI)),

https://www.europarl.europa.eu/doceo/document/TA-9-2021-0122_EN.pdf

and

https://www.europarl.europa.eu/RegData/etudes/STUD/2020/654175/EPRS_STU(2020)654175_EN.pdf

European Parliament resolution of 31 May 2018 with recommendations to the Commission on odometer manipulation

in motor vehicles: revision of the EU legal framework:

https://www.europarl.europa.eu/doceo/document/TA-8-2018-

0235_EN.html,

https://www.europarl.europa.eu/RegData/etudes/STUD/2018/615637/EPRS_STU%282018%29615637_EN.pdf

and

https://www.europarl.europa.eu/RegData/etudes/STUD/2017/602012/IPOL_STU(2017)602012_EN.pdf

World Forum for Harmonization of Vehicle Regulations of the United Nations Economic Commission for Europe

https://eur-lex.europa.eu/eli/reg/2018/858/oj

https://eur-lex.europa.eu/eli/reg/2019/2144/oj

Regulation - 2024/1257 - EN - EUR-Lex

kom (2025) 0180 - Ingen titel

for cars and vans (Euro 6) and lorries and buses (Euro VI), thus ensuring that new vehicles are cleaner in

real driving conditions and that they remain clean for longer than required by the existing (durability) rules.

However, the actual gains in emissions reduction are likely to be significantly reduced due to the final text

adopted by Council and by the European Parliament. In line with the Council position, the new rules keep

the Euro 6 standard for cars and vans as regards exhaust emissions

43,44

. This means that the expected

baseline emission reductions will not materialise, thus increasing the potential impact of roadworthiness

testing in general, and this initiative in particular.

The focus of the RWP is different from the market surveillance legislation mentioned above. Whereas

market surveillance provisions aim to ensure that vehicles continue to meet their type-approval requirements

when placed on the market and for a limited period thereafter, and so are effectively focusing on the

responsibilities of the manufacturer, the RWP focuses on ensuring that minimum standards are maintained

by owners throughout the lifetime of the vehicle. Also, while market surveillance requires testing a limited

number of vehicles per model, PTI applies to almost all registered vehicles. Thus, the RWP complements

the market surveillance legislation in ensuring road safety and the environmental performance of vehicles

during their lifetime. Applying the best available test methods will also help Member States reach the

stricter air quality standards (limit values for the protection of human health) set by the revised

Ambient Air Quality Directive

, notably as regards fine particulate matter and nitrogen oxides.

The Commission is also currently working on an initiative on fair and non-discriminatory

access to in-

vehicle data

, which is crucial for technical inspection centres to be able to carry out their daily tasks. That

initiative will include provisions on access to functions and resources, essential for the provision of data-

dependent services in the automotive sector. It will standardise the relevant datasets and ensure effective

non-discriminatory and secure access for aftermarket and mobility services. A range of automotive service

providers, including vehicle repair and inspection companies and authorities have called for an ambitious

Commission proposal, to ensure a level-playing field and unhindered access to the relevant in-vehicle data

The revision of the PTI Directive could complement the access to in-vehicle data proposal, through specific

provisions facilitating access to the data necessary for technical inspections. More details on synergies with

other EU policy instruments are provided in Annex 16.

Evaluation of the Roadworthiness Package

The Commission conducted an evaluation of the RWP ‘back-to-back’ with this impact assessment. The

evaluation concluded that the RWP was partially successful in achieving its objectives, contributing to

increased road safety, and helping reducing air pollutant emissions from road transport. Defective vehicles

may still not always be detected, as some categories of vehicles are not subject to PTI or RSI in some

Member States, or the frequency or scope of the testing is not adapted to their higher safety and

environmental risk. The identified weaknesses in the current RWP require the Directives to be adapted, to

address not only current needs but also future challenges. The links between the main conclusions of the

ex-post evaluation and the impact assessment are summarised in Annex 11. The evaluation of the RWP is

annexed to this impact assessment report (Annex 17).

https://www.consilium.europa.eu/en/press/press-releases/2023/09/25/euro-7-council-adopts-position-on-emissions-

from-cars-vans-buses-and-trucks/

https://eur-lex.europa.eu/eli/reg/2024/1257/oj

Directive (EU) 2024/2881 of the European Parliament and of the Council of 23 October 2024 on ambient air quality

and cleaner air for Europe (recast)

https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/13180-Access-to-vehicle-data-functions-and-

resources_en

See e.g. open letter from CITA:

https://citainsp.org/wp-content/uploads/2023/03/L2023-006-Data-Act.pdf

kom (2025) 0180 - Ingen titel

Sustainable Development Goals

The initiative contributes to Sustainable Development Goal (SDG) 3 (Ensure healthy lives and promote

well-being for all at all ages), including targets 3.6 (halving the number of deaths and injuries from road

traffic accidents) and 3.9 (substantially reduce the number of deaths and illnesses from hazardous chemicals

and air, water and soil pollution and contamination).

ROBLEM DEFINITION

The problems, underlying problem drivers and consequences that are relevant for the revision of the

Roadworthiness Package are presented in Figure 2. The evidence underlying the problems and their drivers

is based on the best available evidence, including multiple studies involving scientific research, as well as

thorough consultation with experts.

Figure

2: Problem tree

2.1. What is/are the problems?

2.1.1. Presence of unsafe vehicles on EU roads

Although EU roads are the safest in the world and road safety has improved significantly over the last

decades, casualties of road crashes continue to represent high costs to society. Despite the improvement in

vehicle technology, including active safety and intelligent driver assistance systems in new vehicles, unsafe

vehicles still contribute to crashes, either as the main cause or as a contributing factor. A part of unsafe

vehicles is identified at PTI or RSI (i.e., vehicles with major or dangerous deficiencies). Others may not be

detected either because PTI cannot detect them or because they are not subject to testing. These include

vehicles with safety-related tampering and vehicles with incorrectly secured cargo.

Comparable PTI data on vehicles with major and dangerous deficiencies are only available for ten Member

States.

kom (2025) 0180 - Ingen titel

Table

shows the share of those vehicles by vehicle type and Member State, as well as the median by

vehicle type. There is great variability between the PTI results of Member States for each vehicle type,

which points to the need to interpret these data with care. A high share of vehicles with major and dangerous

defects may also reflect variation in the stringency with which testing is applied in a particular country and

not necessarily that vehicles are less roadworthy in that country. What is however clear is that the share of

unsafe vehicles is significant in all Member States and for all vehicle types where such data is available.

kom (2025) 0180 - Ingen titel

Table 1: Share of vehicles with major and dangerous defects in the vehicle fleet, by vehicle type - averages over

2018-2022

Total

Median

18%

20%

22%

48%

38%

25%

12%

20.7%

17%

24.3%

23%

25.5%

18%

23.6%

22%

22.0%

23%

22.0%

4.70%

12.9%

13.7%

31%

20.0%

21%

20.0%

10.0%

N2 (small

M1 (passenger N1 (vans; <3.5

lorries;3.5-12

cars)

tonnes)

11%

21%

25%

19%

24%

28%

50%

44%

26%

15%

30%

15%

33%

52%

55%

N3 (large

lorries ;>12

tonnes)

26%

15%

30%

15%

22%

43%

44%

O1 (trailers

(buses/coaches (buses/coaches

<0.75 tonnes)

<5 tonnes)

>5 tonnes)

11%

10%

16%

26%

14%

35%

55%

29%

16%

26%

15%

25%

48%

22%

14%

24%

12%

11%

24%

22%

14%

26%

O2(trailers

0.75-3.5

tonnes)

14%

26%

O3 (trailers

3.5-12 tonnes)

14%

20%

26%

16%

13%

34%

44%

O4 (trailers

>12 tonnes)

10%

14%

20%

26%

13%

16%

34%

42%

10%

35%

17%

18%

L3-L7

(motorcycles)

Source: Ricardo et al. (2023), Impact assessment support study

While not even a well-developed roadworthiness testing system can detect every defective vehicle through

PTI or RSI, not all defective vehicles will cause a crash either. Various studies

indicate that their share as

a contributing factor of the cause of crashes is between 3 and 19%, depending on the scope and methodology

of the study; for motorcycles, it is 5% to 12% of crashes

. Since PTI has been in place in Europe for a long

time, there are very few recent studies covering EU Member States

. There are similar studies from other

parts of the world

, the most relevant of them being a recent US study

that looked at the difference in

crash rates between states with and without PTI. It shows that states with a safety inspection, even if only a

very simple one for light vehicles, have 5.5% fewer fatalities on average.

Naturally, older vehicles are prone to more frequent breakdowns, and studies have shown that older

vehicles with defects contribute more to the causes of crashes

. The situation is not expected to improve

by itself as the contribution of older vehicles is becoming an increasing concern with the gradual ageing of

the vehicle fleet

. Since cars are responsible for by far the largest share of fatalities (see collision

matrix

Figure

below), and even if technical defects only represent a relatively small share among

the causes of accidents, early detection of those defects can make a significant difference, especially

in terms of road safety.

Martín-delosReyes L.M. et al. (2021), Effect of Periodic Vehicle Inspection on Road Crashes and Injuries: A

Systematic Review,

https://doi.org/10.3390/ijerph18126476

Ricardo et al. (2023), Impact assessment support study on the directives of the roadworthiness package, Contract no.

MOVE/C2/SER/2022-583/SI2.895928, under FWC no. MOVE/2022/OP/0001

Hudec J. and Šarkan B. (2022), Effect of periodic technical inspections of vehicles on traffic accidents in the Slovak

Republic.

Schulz W.H. and Scheler S. (2019), Reducing the Death Toll of Road Accidents in Costa Rica through the Introduction

of Roadworthiness Inspections by the Government, available at SSRN:

https://ssrn.com/abstract=3420341;

Schulz W.H.

and Scheler S. (2020), Getting Ready for Europe: An Empirical Assessment for the Introduction of Periodical Technical

Inspections of Road Vehicles in Turkey, available at SSRN:

https://ssrn.com/abstract=3523602

https://ascelibrary.org/doi/10.1061/JTEPBS.TEENG-7320

https://komunikacie.uniza.sk/artkey/csl-202203-0017_effect-of-periodic-technical-inspections-of-vehicles-on-traffic-

accidents-in-the-slovak-republic.php

For the most recent report on the vehicle fleet, see e.g.:

https://www.acea.auto/publication/report-vehicles-in-use-

europe-2023/

https://transport.ec.europa.eu/background/road-safety-statistics-2022-more-detail_en

kom (2025) 0180 - Ingen titel

Figure 3: Road traffic fatalities in the EU by road user and (other) ‘main vehicle’ involved in the crash

Source: CARE database

Since there is an element of uncertainty in the actual contribution of vehicle defects to road crashes,

a sensitivity analysis was justified.

The shares used in this impact assessment (4% for cars, vans,

HDVs and 6% for motorcycles) are relatively conservative, e.g., compared to the range based on the

literature review presented above. This approach was used to avoid overestimating the benefits.

Secondly, there is an issue related to

safety-related tampering,

which includes the manipulation of engine

performance, torque, maximum speed and improved acceleration, representing an obvious safety risk.

According to experts, the chip-tuning of electric vehicles is as easy as in the case of those equipped with

internal combustion engines, with the added risk of an overheated battery, which can cause fire e.g., in the

case of faster charging or faster discharging (higher performance). According to others, while the share of

tampered cars in the entire fleet remains relatively low, their share is higher among those involved in crashes.

Due to the nature of the problem, available data on it is rather limited. The European Transport Safety

Council, among other stakeholders, has highlighted the issue of safety-related tampering, notably in the case

of powered two- and three-wheelers

. A survey carried out for the Austrian Ministry of Climate Protection,

based on police inspections, found that roughly every second moped was manipulated (tuned) in Austria

In addition,

incorrectly stowed or secured cargo

can slide, roll, tip over and fall off a vehicle, potentially

causing it to overturn and lead to crashes with other vehicles

. To address this problem, the 2014 revision

of the RSI Directive introduced detailed provisions on the inspection of cargo securing, including its

principles, applicable standards, and the assessment of specific deficiencies (as an optional measure). This

was complemented by best practice guidelines

prepared by a Commission expert group to provide

practical advice to anyone involved in loading/unloading and securing cargo, as well as to enforcers. The

guidelines and the corresponding provision of the Directive are non-binding, however. In spite of existing

rules, according to a major operation of Roadpol in Italy in 2019, 22% of the 40,500 inspected heavy goods

Cf. section 6.2.1

and further details in section 6 of Annex 4.

https://etsc.eu/wp-content/uploads/2020-09-ETSC-Briefing-on-Roadworthiness-Package-Implementation-

Reports_update16Oct.pdf

https://www.bmk.gv.at/themen/verkehr/strasse/verkehrssicherheit/vsf/forschungsarbeiten/82_tune-it.html

See e.g., Königsberger Ladungssicherungskreis:

https://www.klsk.de/en/

https://road-safety.transport.ec.europa.eu/eu-road-safety-policy/priorities/safe-vehicles/cargo-securing-and-abnormal-

loads_en

kom (2025) 0180 - Ingen titel

vehicles (HGVs) did not comply with cargo securing requirements

The problem of unsafe vehicles affects not only the owners/users of the defective or tampered vehicles, but

also other road users, especially vulnerable ones. Such example of vulnerable road users are

motorcyclists and while several factors play a role in motorcycle crashes, such as motorcycles’ and

other vehicles’ design (motorcyclists are often overlooked in traffic) and road environment

shortcomings (poor road surfaces, poor road alignment, obstacles, limited line of sight), motorcycle

design elements such as tyres, brakes, frame, suspensions are nonetheless very relevant for the safety

of motorcyclists, and regular control of their technical condition is considered important for their

road safety

Society as a whole is affected by the external cost of crashes through human and medical costs, production

losses, the cost of police, emergency services, congestion, etc.

More systematic and targeted testing of vehicles, using improved and updated test methods, could reduce

the number of such avoidable crashes. 54 out of the 65 stakeholders who replied to the targeted survey

agreed with the problem identified, while only 6 disagreed and 5 were neutral. In the OPC, 78% of

respondents (123 out of 158) agreed that the issue of vehicles circulating on the roads with defects or

tampered components needs to be addressed.

2.1.2. Insufficient control of vehicle air pollutant and noise emissions

Air pollution remains an important cause of poor health in Europe and contributes in particular to

respiratory and cardiovascular diseases.

Road transport has significantly reduced its pollutant emissions since 1990, with the exception of

compounds NH

and N

O. Their recent increase is mainly due to new catalytic systems for the

reduction of NO

in diesel engines and the use of enriched fuel mixtures to control NO

at high load

in petrol engines. While a significant reduction can be seen for both PM

and PM

2.5

, the non-exhaust

fraction of these emissions (i.e. from brake and tyre wear or road abrasion) is increasing

The development of sophisticated emission control technologies has allowed to gradually reduce air

pollutant emissions from road vehicles well (orders of magnitude) below pre-Euro standard levels.

However, overall emissions from road transport are still too high – they alone are responsible for

approximately 40.6% of the total NO

and 10.5% of PM

2.5

emitted in Europe

, and this has serious

implications on human health, the natural environment, and affects the lives of millions, especially in urban

https://etsc.eu/wp-content/uploads/PIN-FLASH39_FINAL.pdf

ERSO Road Safety Thematic Report – Motorcycles, 2023,

https://road-safety.transport.ec.europa.eu/european-road-

safety-observatory

CE Delft et al. (2020), Handbook on the external costs of transport – Version 2019 – 1.1, Publications Office,

https://data.europa.eu/doi/10.2832/51388

The problem analysis focuses on NOx and PM as the main air pollutants from road transport with the highest impact

on environment and health. Other pollutants have not been considered although it is plausible that targeting these two

pollutants will also affect other air pollutants (e.g. CO, HC, SO2).

In 2021 in the EU-27, 253,000 deaths were attributable to exposure to PM

2.5

concentrations above WHO’s guideline level of 5

µg/m

(micrograms per cubic metre of air), 52,000 deaths were attributable to exposure to NO

concentrations above WHO’s guideline

level of 10 µg/m

and 22,000 deaths were attributable to short-term exposure to O

concentrations above 70 µg/m

EEA, Europe's Air

Quality Status, 2023,

Europe’s air quality status 2023 — European Environment Agency.

EEA, Emissions of air pollutants from transport, October 2024

Emissions of air pollutants from transport in Europe | European

Environment Agency's home page

EEA (2023), Air Pollution in Europe; 2023 reporting status,

https://www.eea.europa.eu/publications/national-

emission-reduction-commitments-directive-2023

kom (2025) 0180 - Ingen titel

areas. Various studies have shown that real-world NOx emissions of modern vehicles were above type-

approval limits

. Such exceedances can in some instances (due to tampering, for example) be as high as

older Euro Standards or even pre-Euro NOx emission levels

. Other studies have shown that in the absence

of the appropriate emission reducing technology (selective catalytic reduction (SCR) and diesel particulate

filter (DPF)) on Euro VI HDVs, vehicles can emit up to a factor of 100 more NOx, CO, and PM than the

legal requirements

The findings of the RWP evaluation show that some of the tests used in PTI are no longer sufficiently

sensitive to detect emission failures and the current testing procedures are not fit to meet the EU policy goals

as regards air pollution. Modern vehicle engines and exhaust gas systems have critical detection criteria that

are not covered by the currently prescribed test methods, and current PTI tools are not able to measure PN

and NOx. Considering these shortcomings, the current RWP’s contribution to reducing the number of

vehicles in circulation with high emissions has become less relevant. The measurement of nitrogen oxide

emissions or PM/PN values for new cars are still not covered by the current RWP and there are currently

no EU provisions for testing vehicles for NOx manipulation/defect or manipulation/defect of diesel

particulate filters. The share of vehicles found with defective emission control equipment or exhaust

emissions above the limits specified in the PTI and RSI Directives ranges from around 1-3% to up to 45%

depending on the Member State and the way checks are conducted. Targeted inspections identify higher

shares of over-emitting vehicles. Periodic testing has demonstrated that older vehicles can be much more

polluting than newer ones, as the effectiveness of emissions reduction systems declines with age. Since

some of the defective vehicles emit multiple times over the regulatory limit, even a relatively limited share

of such vehicles can be responsible for a large part of overall road transport emissions. This has been

demonstrated by various studies

In addition, there is evidence

that the emission control equipment of a non-negligible number of modern

vehicles are tampered with, either to avoid immediate replacement of filters or the cost of consumables,

such as diesel exhaust fluid (DEF)

required for the proper functioning of SCR

. Various tampering

techniques have been developed to alter on-board diagnostic information and to avoid that the vehicle

automatically switches to low-power (or limp) mode, e.g., after it has run out of DEF for a long time. This

is consistent with the observation that a small number of “high emitters” are generally responsible for a

disproportionate fraction of the overall emissions (e.g., a TNO study

indicates that 6% of vehicles

defective emission control systems caused 36% of road transport NOx emissions). A recent study involving

remote sensing technology screening a large number of vehicles in Flanders, Belgium showed similar

results for particle emissions due to DPF failures

see e.g., TNO report on NOx emissions of eighteen diesel light commercial vehicles:

http://resolver.tudelft.nl/uuid:21191e19-2dc7-4468-8559-1075ed6279f7

Giechaskiel, F. et al. (2022), Effect of tampering on on-road and off-road diesel vehicle emissions.

Ricardo et al. (2023), Impact assessment support study on the directives of the roadworthiness package, Contract no.

MOVE/C2/SER/2022-583/SI2.895928, under FWC no. MOVE/2022/OP/0001Ricardo et al. (2023), Impact assessment

support study

Such as TNO (2022),

http://resolver.tudelft.nl/uuid:b5d127c3-303c-4013-b1ac-c9ac01f66e2d

and CARES (2023),

https://cares-project.eu/emission-factors-lez-impact/

Notably from roadside checks reported by inspectors of national authorities, including with the use of plume chasing

technology:

https://citainsp.org/wp-content/uploads/2021/11/5-CITA-17-11-2021-for-upload.pdf

Diesel exhaust fluid (DEF), also known as AUS 32 (aqueous

urea solution 32%)

and marketed as AdBlue.

A basic illustration of the main components of an exhaust aftertreatment system is available at:

https://www.autoserviceworld.com/understanding-diesel-exhaust-aftertreatment-systems/

TNO report on NOx emissions of eighteen diesel light commercial vehicles:

http://resolver.tudelft.nl/uuid:21191e19-

2dc7-4468-8559-1075ed6279f7

Hooftman N., Ligterink N., Bhoraskar A., (2020), Analysis of the 2019 Flemish remote sensing campaign.

Commissioned by the Flemish Government - Flanders Environment Agency - Team Air quality policy.

kom (2025) 0180 - Ingen titel

As regards the impacts of the problems on pollutant emissions, the links between cause and effect

are more straightforward than in the case of road safety. Even though in the absence of accurate

emission testing available on a wide scale, the share of high-emitting vehicles and their contribution

to total emissions can only be estimated, the available studies applying portable emission

measurement systems (PEMS), recent remote sensing campaigns and the first results of newly

introduced particle number (PN) testing in three Member States provide a high level of confidence

as regards the scale of the problem, and the calculations of the impacts.

As outlined in section 1, road transport is by far the largest source of noise pollution in Europe and is the

second most harmful environmental stressor after air pollution

. Modified or defective exhaust systems

can also contribute to noise pollution. The threshold of noise above which it is considered a nuisance can

vary. In the OPC, 91 out of 149 respondents expressed the view that it is very important to address the

problem of noise-related tampering/non-compliance in vehicles and 13 had no opinion. Most respondents

to the survey and interviews conducted as part of the evaluation believed that technological and market

developments had had a low impact on reducing the number of vehicles with tampered or defective noise

control systems (46 of 75 respondents; 15 did not know or did not respond). Representatives of the

automobile as well as motorcycle manufacturers (ACEA and ACEM) agree that illegal modifications

leading to single-event noise peaks need to be addressed through consistent control

While these vehicles are supposed to be repaired or taken out of circulation, there are still many vehicles

with defective or tampered emission control systems that go undetected and continue to cause avoidable

damage. Noise tampering mainly affects powered two-wheelers, which are not subject to roadworthiness

testing in every Member State. The problem of air pollution and noise generated by vehicles mainly affects

people living in the vicinity of major roads, in particular in urban areas, and especially the most vulnerable.

Lower income groups tend to be exposed to higher levels of air pollution, while older people, children,

adolescents, and those with pre-existing health conditions are more susceptible to negative effects of air

pollution

. 56 out of the 67 stakeholders who replied to the targeted survey agreed with the problem

identified, while only 4 disagreed and 7 were neutral.

2.1.3. Roadworthiness Directives are not effective in enforcing rules in EU cross-border

traffic and trade of vehicles

One of the objectives of the RWP was to facilitate free movement for EU citizens and ensure the smooth

functioning of the internal market

. This is reflected in different elements of the RWP, including the mutual

recognition of roadworthiness certificates among EU Member States (as part of the PTI Directive), in

combination with the provisions of the VRD Directive aiming to ensure the authenticity, accuracy, and

mutual recognition of vehicle registration documents across EU Member States. Brought together, these

should facilitate the enforcement of the rules, efficient cross-border transport, and prevention of fraudulent

practices, eventually contributing to better road safety and less polluting vehicles on the roads.

According to the findings of the evaluation, communication between authorities across national borders

improved following the adoption of the RWP. The PTI and RSI Directives established contact points

through which information can be more swiftly exchanged between Member States. However, the

see e.g. DIAS (2022), D6.5 Impact assessment and guidelines for future anti-tampering regulations, or TNO (2022),

Approaches for detecting high NOx emissions of aged petrol cars during the periodic technical inspection. R10659v2

https://www.eea.europa.eu/publications/managing-exposure-to-noise-in-europe/noise-in-europe-updated-population-

exposure

https://www.acea.auto/files/ACEA-position-paper-Vehicle-noise-setting-appropriate-limits.pdf

and

https://acem.eu/images/publiq/2021/ACEM_Position_Paper_Sound_Emissions_2021.pdf

https://www.eea.europa.eu/en/topics/in-depth/air-pollution

Cf. recitals 1 and 3 of the Directive 1999/37/EC (VRD) and recital 24 of Directive 2014/45/EU (PTI)

kom (2025) 0180 - Ingen titel

evaluation also highlighted that Member States still report difficulties in effectively enforcing road safety

measures in EU cross-border traffic and vehicle trade. These have their origin in: (a) Member States

registering different sets of vehicle data, and (b) difficulties for competent authorities in accessing vehicle

Member State. These difficulties make the re-registration of vehicles less efficient and more cumbersome

for citizens

. Related to cross-border trade of vehicles, the evaluation of the RWP found some

incoherencies between the VRD Directive and Regulation (EU) 2018/858 on type-approval requirements

in some cases, in the VRD Directive, definitions of the vehicle registration data and terminology do not

correspond to those in the type-approval legislation. This leads to confusion and potential errors in recording

vehicle information at the time of re-registration. Furthermore, difficulties in the cross-border exchange of

information between Member States’ authorities can also negatively impact the fight against the widespread

malpractice of odometer tampering which, by itself, can negatively affect road safety and the environment

(due to poorer maintenance). It is also directly affecting consumers given that mileage is an important

determinant of used vehicles’ market value.

Odometer tampering rates were estimated at 20 to 40% for cars imported in EU15 countries and 30 to 80%

in EU12, according to a study commissioned by the European Parliament

, while other studies indicate the

share of tampered vehicles to be between 5 and 12% of used cars in national sales and much more, between

30 and 50%, of cross-border sales

. According to the support study of the European Parliament’s 2018

resolution on odometer manipulation in motor vehicles in the EU, the total economic costs of odometer

fraud in second-hand cars traded cross-border in the EU could be estimated at around EUR 8.77 billion per

year

. This was found mainly due to the lack of effective cooperation between Member States' authorities

and an insufficient exchange of information on mileage readings of odometers in vehicles traded across the

Member States' borders. More recent estimates provided by CarVertical

, based on analysis of vehicle

history reports, suggest overall lower odometer fraud rates for most of the countries reported that those in

the European Parliament study. Drawing on CarVertical and other assumptions, the impact assessment

support study

shows however that fraud rates are still estimated to be significant (i.e., 2.2 to 10% of used

cars in national sales and 4.4 to 25.7% of cross-border sales)

Even though odometer manipulation is a punishable offence under the PTI Directive, the fact that odometer

readings are recorded only at PTI does not prevent fraud since most cars and vans are not tested before they

are four years old and, in most Member States, only every two years thereafter. Furthermore, the evaluation

of the RWP also reported that regarding the obligation to introduce effective and dissuasive penalties when

an odometer is found to have been manipulated, the national measures appear in many cases rather generic,

not specifically aimed at odometer fraud. 39 out of the 60 stakeholders who replied to the targeted survey

agreed with the problem identified, while only 5 disagreed and 16 were neutral.

As illustrated by various complaints and SOLVIT requests received by the Commission.

https://eur-lex.europa.eu/legal-content/EN/TXT/PDF/?uri=CELEX:32018R0858

TRT (2017), Research for TRAN Committee (European Parliament) - Odometer tampering: measures to prevent it.

https://www.europarl.europa.eu/RegData/etudes/STUD/2018/615637/EPRS_STU%282018%29615637_EN.pdf

Overall mileage fraud analysis is available at:

https://www.carvertical.com/blog/research-what-countries-have-the-

highest-percentage-of-cars-with-a-fake-mileage,

and in the CarVertical Market transparency index:

https://www.carvertical.com/transparency-index.

Specific analysis of the share of odometer tampering for national and

imported second hand vehicles is available at:

https://www.carvertical.com/blog/research-local-or-imported-cars-have-

more-mileage-rollbacks.

Ricardo et al. (2023), Impact assessment support study on the directives of the roadworthiness package, Contract no.

MOVE/C2/SER/2022-583/SI2.895928, under FWC no. MOVE/2022/OP/0001

See Annex 4 (section 2) for more detailed explanations on the estimations, and an overview by Member State.

kom (2025) 0180 - Ingen titel

2.2. What are the problem drivers?

2.2.1. PTI-methods not available to test electric vehicles, electronic safety & driver

assistance systems (PD1)

This problem driver links to problem 1 (Presence

of unsafe vehicles on EU roads).

The existing rules on

roadworthiness testing were designed more than 10 years ago, with the Commission’s proposal made in

2012. At the time, the share and expected development of the electric vehicle (EV) market was significantly

lower than today

, which explains why there are no EV-specific requirements in the PTI Directive. The

same applies to electronic safety and driver assistance systems.

The General Safety Regulation

requires that, from 6 July 2022, new vehicle types are equipped with

certain advanced driver assistance systems (ADAS), including intelligent speed assistance, reversing

detection with camera or sensors, attention warning in case of driver drowsiness or distraction, event data

recorders, an emergency stop signal (in all road vehicles), as well as lane keeping systems and automated

braking in cars and vans. These features will be mandatory on all vehicles registered from 7 July 2024

onwards. Thanks to the requirements of the GSR, new car and van models sold since July 2022 and every

new vehicle sold from July 2024 will be due for PTI between 2026 and 2028. Trucks and buses featuring

technologies helping to recognise blind spots, warnings to prevent collisions with pedestrians or cyclists

and tyre pressure monitoring systems will have to undergo their first roadworthiness tests even earlier

(usually one year after the first registration).

The RWP evaluation found that systems introduced by the revision of the GSR increases the relevance of

vehicle roadworthiness testing to verifying the operation of these mandated electronic systems. These

systems may malfunction, require software updates to ensure intended performance, and they could be the

target of tampering. In terms of keeping up of the RWP with the technological and scientific progress, most

of the stakeholders interviewed in the context of the evaluation considered that it is essential to update the

directives to include the functioning of ADAS and advanced lighting, which have been fitted in cars for

around a decade but are not tested by standard PTIs. Similarly, the survey respondents, especially ministries,

road safety authorities and PTI bodies, considered that the current RWP directives and their objectives

follow technological advancement only to a limited extent. The technology used in vehicles has surpassed

what the current directives cover and new rules for inspection of new safety systems, such as ADAS, are

needed. Although both EVs and ADAS bring about significant benefits by reducing emissions and

improving road safety, they also come with new risks to be mitigated. In the case of EVs, including plug-in

hybrids, the high voltage systems can be a source of such risks, which, if damaged, can overheat and cause

fire. While a few Member States have introduced national requirements (e.g., FR, NL) in relation to the

inspection of EVs, these are not generally applied in the EU. For ADAS, it is the possible malfunctioning

of the systems themselves that may create safety hazards. However, none of these are currently tested during

periodic technical inspections.

Next to the research and development efforts needed to define the appropriate test methods, an important

barrier to their application is the difficulty for inspection centres to access the necessary in-vehicle data.

Although the Commission Implementing Regulation (EU) 2019/621 requires that manufacturers make

certain vehicle data available to facilitate PTI tests, it does not apply to the data related to items/components

that are not part of the current minimum requirements on items to be tested. According to the findings of

the evaluation, there is data incoherence between the RWP and relevant type-approval legislation due to

While there were only about 200,000 EVs, including PHEVs, in Europe in 2014 (and much fewer in 2012 when the

proposal was made), in 2022, there were 7.8 million EVs on European roads,

https://www.iea.org/reports/global-ev-

outlook-2023/trends-in-electric-light-duty-vehicles

https://eur-lex.europa.eu/eli/reg/2019/2144/oj

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divergence of safety-relevant vehicle data. The interview respondents considered there was a common

problem with the RWP regarding the limited direct access to in-vehicle data and functions for authorised

inspection service providers. For example, even two models of the same manufacturer can require different

file formats, which makes the use of reference data very difficult and time-consuming. 74% of the OPC

responses (116 out of 156) were in favour of the need to address this problem driver; a similar percentage

of support was expressed by industry representatives during the targeted survey (58 out of 76 responses).

2.2.2. Current PTI & RSI-methods not suited to measuring the emission performance of

modern vehicles (PD2)

This problem driver affects problem 2 (Insufficient

control of vehicle air pollutant and noise emissions).

The existing Directives require exhaust gas emission testing of diesel vehicles using opacity measurement,

or, in the case of Euro 5/V and Euro 6/VI vehicles, by reading the vehicle’s on-board diagnostic (OBD)

system. While exhaust gas opacity testing may detect a defective emission control system without a particle

filter in an older vehicle (pre-Euro 5/V) and has thus been considered sufficient to test the compliance of

those vehicles, multiple laboratory tests

have proved that it cannot detect a malfunctioning or even

tampered diesel particle filter (DPF). DPFs were introduced to comply with significantly stricter limits than

before Euro 5/V and the emissions without a DPF could be about an order of magnitude (or two) higher

Even in a Euro 4 vehicle equipped with a defective DPF, the exhaust’s opacity may be lower than the

instruments’ resolution. Studies have also shown that even when high smoke emissions are measured, in

most cases the OBD does not indicate any failure.

Furthermore, while the newly developed method of particle number (PN) counting

has demonstrated high

levels of particle emissions in vehicles with defective DPFs, e.g., close to 10% of Euro 5 and 6 vehicles

tested in Belgium in 2022, the OBD showed malfunctioning in only 0.72% of the cases

. This illustrates

the extent to which the current emission test requirements of the PTI and RSI Directives are obsolete and

inadequate concerning modern diesel vehicles. Concerns about the ineffectiveness of smoke opacity tests

were also expressed by stakeholders surveyed during the evaluation. The applicability of PN measurement

has not yet been sufficiently tested for vehicles equipped with positive ignition engines, but relevant research

is ongoing. To address the issue of high NOx emissions, various methods have been studied to measure

them

. However, while NOx emission limits are set by type-approval, and RDE (Real Driving Emissions)

tests have significantly tightened the requirements on new vehicles, the monitoring of NOx emissions from

road vehicles is currently not part of PTI.

Such as those carried out by the Commission’s Joint Research Centre: Comparisons of Laboratory and On-Road Type-

Approval Cycles with Idling Emissions. Implications for Periodical Technical Inspection (PTI) Sensors,

https://doi.org/10.3390/s20205790

and Evaluation of Measurement Procedures for Solid Particle Number (SPN)

Measurements during the Periodic Technical Inspection (PTI) of Vehicles,

https://doi.org/10.3390/ijerph19137602.

See e.g.,

https://environnement.brussels/media/1883/download?inline

Already applied by Belgium, the Netherlands, Germany as well as Switzerland, and referred to in the Commission’s

recommendation on particle number measurement,

https://eur-lex.europa.eu/eli/reco/2023/688/oj.

Figures reported by GOCA Vlaanderen for July 2022-April 2023: 12.4% of Euro 5 and 2.8% of Euro 6 vehicles failed

with the current 1.000.000 1/cm

limit; 16.8% and 4.8%, respectively, would have failed the recommended limit of

250.000 1/cm

E.g., Fernández (2022), Suitability Assessment of NOx Emissions Measurements with PTI Equipment,

https://doi.org/10.3390/vehicles4040050;

CITA (2022),

Monitoring of NOx emissions as part of the PTI – CITA

International Motor Vehicle Inspection Committee (citainsp.org);

Franzetti et al. (2023), Assessment of a NOx

Measurement Procedure for Periodic Technical Inspection (PTI) of Light-Duty Diesel Vehicles,

https://doi.org/10.3390/en16145520.

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2.2.3. Limited technical possibilities to detect vehicles with defective or tampered

components (PD3)

This problem driver is linked to all three problems. Firstly, together with PD1 (PTI-methods

not available

to test electric vehicles, electronic safety & driver assistance systems),

it is one of the reasons why there are

still, and will continue to be,

unsafe vehicles on the roads.

While new vehicle technology may require new

ways of testing (PD1), there are vehicles on the roads today with defects that carry a potential safety risk

and that PTI cannot detect, notably due to the limited vehicle data available to testing centres (or repair

shops). For example, where a windscreen of a vehicle equipped with cameras is replaced, precise calibration

requires not only the manufacturer’s specifications, but also the vehicle’s relevant data history (which for

some vehicles can provide details of the last time the vehicle underwent a recalibration). Such information

is currently not available to PTI.

Similarly, unauthorised modifications to the vehicle’s engine management system to increase its power may

not be detected without access to the relevant in-vehicle data

. Such tampering is relatively easy, and

devices are widely available, for internal combustion engines as well as for electric vehicles (a simple web

search would deliver multiple results). The situation is similar in the case of motorcycles

. The ongoing

electrification of powered two-wheelers, especially mopeds, has apparently led to an increase in the same

kind of tampering of those vehicles, with multiple tutorials available online. Since manipulation is so easy

in the case of these vehicles, it is difficult to detect it even where such vehicles are subject to periodic testing

as the modifications can also be easily reversed. These vehicles represent an increased safety risk, in

particular in urban areas.

Secondly, tampering with emission control systems is equally easy with various solutions offered online

even explaining why it is “good” for the user to disable the selective catalytic reduction (SCR) system,

which requires diesel exhaust fluid (DEF, or AdBlue). While DEF is a necessary consumable for the SCR

to significantly reduce the amount of NOx emissions, since running out of DEF may cause the vehicle not

to start, it is a convenient (and often significantly cheaper) solution to deactivate the entire system. It can be

especially viable in the case of commercial vehicles, where entire fleets may be tampered to decrease repair

and maintenance costs

100

. Together with PD2 (Current

PTI & RSI-methods not suited to measuring the

emission performance of modern vehicles),

this contributes to the

insufficient control of vehicle air

pollutant and noise emissions.

Noise-related tampering, i.e., removing the exhaust silencer (or dB killer)

of a motorcycle is similarly easy with abundant instructions available online. According to ACEM and some

experts in vehicle testing, PTI is not sufficiently effective when it comes to such tampering.

Thirdly, tampering with odometers is also a lucrative business and detecting it has been a challenge across

the EU, which negatively affects the effectiveness of the RWP in

enforcing rules in EU cross-border

traffic and trade of vehicles.

Recording odometer readings at PTI may have somewhat improved the

traceability of odometer history, or helped detect fraud (likely too late, when the vehicle is due for PTI with

its new owner). However, with PTI being a pre-announced inspection, it is not difficult to readjust the

mileage of the vehicle just before or after. Thus, in the absence of a better way to trace odometer history,

Before a recent fatal crash in Budapest, the maximum power of the vehicle causing the crash was increased from 612

to 690hp without it being noticed at PTI.

See e.g.

https://buy-tuning-files.com/chiptuning/why-modify-your-motorcyles-rev-limiter-and-how-to-do-it/

See e.g.,

https://117speed.co.uk/adblue-removal-everything-you-need-to-know/;

https://www.canbusemulator.com/en/

100

See e.g., a case uncovered in Spain:

https://www.guardiacivil.es/es/prensa/noticias/6944.html

and

https://www.europol.europa.eu/media-press/newsroom/news/haulier-in-spain-caught-cheating-emission-regulations-

designed-to-prevent-air-pollution

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mileage tampering remains largely possible in most Member States, and especially across borders

101

2.2.4. Vehicle identification & status data not sufficiently available to, and recognised

among, enforcing authorities (PD4)

This problem driver links to problem 3 (Roadworthiness

Directives are not effective in enforcing rules in

EU cross-border traffic and trade of vehicles).

In addition to the issues mentioned under PD3, the inefficient

exchange of information among Member States further contributes to limiting the effectiveness of the

Directives. While most stakeholders consider that the RWP has contributed to facilitating communication

among Member States, they agree that vehicle identification and status data are still not sufficiently available

to enforcing authorities. As mentioned in Section 2.1.3, there are sometimes significant differences in the

data elements recorded in national vehicle registers, largely due to the high number of optional data

elements, including those that are not even specified in the VRD Directive. Table 2 summarises the diversity

in the registration of various data elements. 224 data elements are stored by only some of the Member States

(i.e., not by all, and not by any of them).

Table 2: Summary of the registration of various data elements

Number of data elements M1 Percentage of the MS that stores the item

11 data elements were stored by all of the MS (100%)

23 data elements were stored by a clear majority of the MS (80% – 99 %)

135

135 data items were stored by a substantial number of MS (30% – 79 %)

66 data elements were stored by a minority of the MS (1% – 29 %)

38 data elements were stored by none of the MS (0%)

102

Source: EReg/EUCARIS

In addition to the regulatory framework provided by the VRD Directive, EReg, the Association of European

Vehicle and Driver Registration Authorities, has worked on the voluntary harmonisation of registration

procedures and data quality, including on the scope of data that should be stored in vehicle registers to

facilitate cross-border trade (re-registrations) and issued various reports on the topic

103

Although the VRD Directive requires Member States to assist one another in the implementation of the

Directive, it merely allows exchange of information and only hints at the possibility that this could be done

electronically. This has led to a situation where several Member States use EUCARIS

104

for the exchange

of vehicle registration data, mileage data, PTI data or roadside inspection (RSI) reports. However, while

many Member States use EUCARIS for various services, not all of them use it systematically for the

relevant exchange of data. The lack of clear rules as regards the exchange of vehicle related information

among Member States therefore further complicates smooth communication between authorities.

To implement requirements of the RSI Directive to notify the Member State of registration of any major or

dangerous deficiencies found at RSI, since June 2020, the notifications must be sent using the RSI system

105

built on the functionalities of the European Register of Road Transport Undertakings (ERRU). ERRU and

101

While Belgium and the Netherlands have introduced dedicated systems with databases keeping much more frequent

odometer readings than what PTI can offer, and thus significantly reducing odometer fraud in both countries and between

them, such systems do not exist elsewhere and detecting odometer fraud, especially in imported vehicles, is less likely.

102

https://www.ereg-association.eu/media/2742/final-report-topic-group-xxi-proposal-on-the-registration-of-vehicle-

data.pdf

103

https://www.ereg-association.eu/topic-groups/topic-group-xxi/

104

EUCARIS (European Car and Driving Licence Information System) is a system developed by and for governmental

authorities to help fighting car theft and registration fraud. It enables the sharing of vehicle and driving licence

information between EU and non-EU countries:

https://www.eucaris.net/

105

Commission Implementing Regulation (EU) 2017/2205 on detailed rules concerning the procedures for the

notification of commercial vehicles with major or dangerous deficiencies identified during a technical roadside

inspection:

https://eur-lex.europa.eu/eli/reg_impl/2017/2205/oj

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RSI messaging system, as well as several other road transport-related applications are hosted by the

Commission and use a central hub (MOVEHUB) to interconnect national registers. While certain EU

legislation requires the use of EUCARIS

106

, and others, including the RSI Directive, refer to the

MOVEHUB for data exchange, there is no legal requirement to use such systems to facilitate the re-

registration of vehicles and the implementation of the PTI and VRD Directives. The inability to effectively

exchange a real-time data on the vehicle (de)registration status, including the information on cases when a

vehicle is temporary de-registered or its ownership has changed, contribute to the problem of a low

traceability of vehicles across the EU. Such administrative and regulatory failures hinder the uncovering of

illegal activities such as the illegal trade or illegal dismantling of vehicles, leading to the problem known as

“missing vehicles”

107

Certain optional data registered in one Member State are not recognised by another EU country for re-

registration. The reason is that the second Member State registers a different set of data. This may concern

data related to the owner, the mass, the category, or the exhaust emissions of the vehicle. Moreover, even

though there is significant level of harmonisation in roadworthiness testing, there are very few cases where

the Member State of registration recognises the validity of a PTI certificate issued in another Member State

(one example is the Netherlands accepting PTI conducted in certain PTI centres in Spain). Such lack of

recognition of registration data and PTI reports lead to inefficiencies in administrative processes and cause

avoidable administrative burden for vehicle owners.

Stakeholders consulted during the evaluation emphasised in their interviews that digital data exchange and

harmonisation of vehicle documents is needed for streamlining the vehicle re-registration process since

standardising the content and format of vehicle files would facilitate the digital transfer of registration

information between national databases and reduce the administrative burden and costs associated with the

process. The interviewees stressed the need for a legal framework to support this exchange of data and

digital services for efficient re-registration process. 67% of the OPC responses (100 out of 149) were in

favour of the need to address this problem driver; a similar percentage of support was expressed by industry

representatives during the targeted survey (47 out of 72 responses).

2.2.5. Certain vehicles are not (sufficiently) tested for their roadworthiness (PD5)

Problem driver 5 relates to the fact that certain vehicle categories are not covered by or not necessarily tested

under the PTI/RSI Directives and, as a result, PTI/RSI is only required for such vehicles in a few Member

States. Furthermore, frequency or scope of testing of certain vehicles is not adapted to the higher safety and

environmental risk associated with them (very frequent use or vehicle age). This directly affects the first

two problems, i.e., the presence of unsafe vehicles on EU roads and insufficient control of air pollutant

and noise emissions. Indirectly, it also has an influence on the third problem, in that testing light vehicles

annually from the date of their first registration (as is the case for HDVs), and at the roadside, could also

increase the effectiveness of the directives, notably in preventing odometer fraud.

In 2014, the scope of the PTI Directive was extended to faster tractors (design speed >40km/h) and larger

two- and three-wheel vehicles and quadricycles (equipped with internal combustion engines >125cm

effective from January 2022. However, the Directive allows for exempting motorcycles, tricycles and heavy

quadricycles (L3e, L4e, L5e and L7e) from PTI “where

the Member State has put in place effective

alternative road safety measures”

and on condition that the Commission is notified. At the end of 2023,

106

Such as

https://eur-lex.europa.eu/eli/reg_impl/2021/133/oj

and the Commission proposal on the revision of Directive

2015/413 on facilitating cross-border exchange of information on road-safety-related traffic offences.

107

This problem and its drivers are discussed in the Impact Assessment Report accompanying the proposal for an ELV

Regulation (SWD (2023)256 final) mentioned in section 1.

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eight Member States

108

made use of this possibility. France introduced PTI for powered two- and three-

wheelers and quadricycles in April 2024. As such, the scale of the problem is expected to reduce

significantly, especially thanks to the introduction of PTI in France.

Agriculture and forestry tractors may also be exempted. Since they are not covered by the PTI Directive,

mopeds are only subject to periodic roadworthiness testing in some Member States (e.g., Austria, Croatia,

Spain). Although not in the scope of the PTI Directive, more than half of the EU Member States (16) have

provisions for mandatory PTI for light trailers (3 Member States have provided this only for the larger O2-

category, i.e., with maximum mass above 750 kg and up to 3500 kg), while others exempt them under

certain characteristics or conditions of operation

109

With regards to the RSI Directive, the requirements on technical roadside inspections currently only apply

to commercial vehicles of more than 3.5 tonnes, while vehicles below this weight and their trailers are

exempted from inspections in most Member States.

Finally, and most importantly, only 16 Member States apply more frequent (yearly) roadworthiness tests to

older cars (>10 years)

110

, that is, eleven, including the Member States with the largest fleets

111

, do not,

which represent an increased safety and environmental risk. Since the car and van fleets of these Member

States represent roughly half of the EU fleet, and the vehicles older than 10 years among them are

about half of that, annual testing of vehicles older than 10 years would affect around 25% of the EU

light duty vehicle fleet.

112

2.2.6. Interlinkages between the problem drivers

Some of the problem drivers are interlinked with each other. This is the case in particular with PD3

(Limited

possibilities to detect vehicles with defective or tampered components),

which is influencing or influenced

by all the other problem drivers. EVs and ADAS represent new technologies and test methods for such

systems are very recent or just being developed and are not widely used yet (PD1). The lack of legal

requirement to test such systems during PTI and RSI for their potential defects may also present a safety

risk. PD3 is also linked to PD2

(Current PTI & RSI-methods not suited to measuring the emission

performance of modern vehicles)

in a similar way as to PD1. Emission control systems have also evolved

considerably and developing adequate test methods to verify their functioning in a PTI-environment (i.e.,

requiring a quick, simple, and cheap method) has taken some time, which partly explains why the current

PTI and RSI emission test requirements are outdated. While for the purpose of detecting tampered vehicles,

RSI has the advantage of the drivers not knowing that they would be tested, it has the limitation that it is

only organised in campaigns and can therefore only screen a small subset of the vehicle fleet. PD3 is linked

to PD4

(Vehicle identification & status data not sufficiently available to, and recognised among, enforcing

authorities)

in that in most Member States it is currently not possible to verify whether the odometer reading

of a vehicle is correct or not. Finally, it is linked to PD5

(Certain vehicles are not (sufficiently) tested for

their roadworthiness)

since it is not possible to detect defective or tampered vehicles that are not tested.

2.3. How likely is the problem to persist?

Problem 1 - Presence of unsafe vehicles on EU roads.

While technological development is likely to further

improve vehicle safety, the uptake of new technologies in the EU vehicle fleet would take some time, and

108

BE (testing is only required before selling or after a crash), DK (requiring roadside checks instead), FI, FR, IE, MT,

NL, PT (PTI only above 250 cm

). FR introduced PTI for powered two- and three-wheelers and quadricycles in 2024.

109

DK, EL, FI, FR, NL, IE, PT exempt all light trailers, while PL, SK, BE and ES exempt O1.

110

Cf. section 2 of Annex 6.

111

Those eleven are DE, FR, IT, CY, CZ, DK, EL, HU, LT, MT, and SK.

112

Sections 4.1.9, 4.2.10 and 5 of Annex 4.

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some of the new features may also bring about new risks. Similarly, while tampering may be made more

difficult by technical solutions, it is unlikely that it would disappear without enabling vehicle testing to

detect illegal modifications, notably of the engine management software e.g., through securing better access

to in-vehicle data. Thus, in the absence of EU level intervention, the problem is likely to persist. Member

States may take unilateral measures (e.g., introducing PTI for specific vehicle categories, specific methods

for the testing of EVs or ADAS). However, these measures cannot replace the coordinating and harmonising

effect of the three Directives, with the risk of possible distortions of the internal market and only partially

addressing the problem.

Problem 2 - Insufficient control of vehicle air pollutant and noise emissions.

The problem of insufficient

control of vehicle air pollutant emissions would persist as long as vehicles equipped with internal

combustion engines (ICE) are on the roads. Although with stricter emission standards and gradual

electrification the number of vehicles generating tailpipe emissions will decrease, they will still be

circulating in the EU decades from now. While the proposed Euro 7 standard should address tampering and

durability more effectively than its predecessors, vehicle aging and defects are unlikely to be completely

overcome and vehicle inspection will continue to be key. Without updating the current emission test

requirements at EU level however, Member States may not introduce the most effective and efficient test

methods already available based on Commission recommendations. Similarly, while more Member States

may start experimenting with roadside noise testing e.g., as mentioned in section 1, it is unlikely that the

problem of noise vehicles would reduce significantly without a more systematic and coordinated approach.

Problem 3 - Roadworthiness Directives are not effective in enforcing rules in EU cross-border traffic and

trade of vehicles.

Without EU level intervention, certain Member States may take unilateral or bilateral

measures, such as systematic recording (and possibly exchanging) of odometer readings, or develop

agreements to recognise each other’s roadworthiness certificates. However, the systemic problem of

insufficient and inefficient exchange of roadworthiness-related vehicle data would remain, hindering

effective implementation and enforcement of existing rules.

Foresight tools.

The analysis incorporates throughout all its dimensions relevant

foresight tools.

It does so

to anticipate trends and issues that may affect the initiative and build a robust, future-proof evidence base

for its likely impact. The megatrend “Accelerating technological change and hyperconnectivity” will have

a significant impact on the road transport sector and is relevant for the problems related to the presence of

unsafe vehicles on EU roads and the insufficient control of vehicle air pollutant and noise emissions.

However, as explained above, technological change on its own would not be able to address these problems,

or at least not for decades from now. The 2022 Strategic Foresight Report

113

points to the potential of

digitalisation and artificial intelligence to boost the emergence of more efficient mobility solutions, with a

new generation of digital technologies enabling a major shift towards more sustainable mobility for

passengers as well as heavy-duty freight transport. This trend will have an impact on all three problems

mentioned above. For example, while digital solutions play a crucial role in innovative safety features and

highly sophisticated emission control systems, the trend has also led to new tampering techniques in both

areas. The trend will also play a key role in addressing the third problem, however, in itself, it will not be

sufficient to resolve regulatory failures. The megatrend “climate change and environmental degradation”

114

is directly related to the insufficient control of vehicle emissions, identified as one of the main issues to be

addressed in line with the air quality legislation referred to in section 1. The same foresight report identified

“enabling a greener transport sector with digital technologies” as one of the areas where the twinning of the

green and digital transitions is expected to have a major effect. As regards the expected transformation of

the vehicle fleet over the next decade, certain automakers (e.g., Volvo) plan to sell only EVs as of 2030.

113

https://commission.europa.eu/strategy-and-policy/strategic-planning/strategic-foresight/2022-strategic-foresight-

report_en

114

https://knowledge4policy.ec.europa.eu/foresight/tool/megatrends-hub_en

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Those cars will also be connected and featuring the ADAS required by the General Safety Regulation.

HY SHOULD THE

ACT

3.1. Legal basis

The legal basis giving the EU the right to act is Article 91 of the Treaty on the Functioning of the European

Union (TFEU. In particular, Article 91(1)(c) provides that the Union has competence in the field of transport

to lay down measures to improve transport safety.

3.2. Subsidiarity: Necessity of EU action

In the absence of the EU level intervention, Member States would continue to carry out periodic and

roadside inspections, but it is very unlikely that test methods and the scope of inspections required by the

EU acquis (e.g. testing brakes, suspension and emissions reduction equipment, etc.) would be applied in a

harmonised or coordinated manner. Different and piecemeal solutions would be applied, which would lead

to even larger differences in the safety and environmental performance of vehicles than today, with the risk

of distorting the internal market, and creating further barriers to free movement. The initiative therefore

addresses safety and environmental protection needs with “Union relevance”.

Road transport, especially freight, is an international sector, with vehicle approval regulated at the EU and

international (UNECE) level. Therefore, it has by nature a strong cross-border dimension. According to the

evaluation and the various targeted stakeholder consultations carried out as part of the revision process, the

RWP has been considered to have contributed to road safety and environmental protection in the EU and

has even had positive spill-over effects in neighbouring countries.

The identified problems apply across the entire Union and have the same underlying causes. At the same

time, there is widespread agreement among national authorities and industry experts that the current

Directives are no longer aligned with the latest regulatory and technological developments in vehicle safety

and emission control. In the absence of EU action, EU Member States may implement national solutions

and will work in an uncoordinated and non-harmonised way. This could undermine the harmonised safety

and emission standards.

3.3. Subsidiarity: Added value of EU action

As road transport and the automotive industry are international sectors, it is much more efficient and

effective to address the issues at the EU level than at the level of Member States. While national practices

differ historically, a certain minimum level of harmonisation in vehicle testing and commonly agreed

solutions to exchange vehicle data between Member States is more effective than multiple uncoordinated

national solutions. With common rules applied to testing modern vehicle technologies (EVs, ADAS, and

the most recent emission control equipment), Member States will realise economies of scale and testing

equipment manufacturers can operate on a more homogenous market. The functioning of the internal

market would also be improved by vehicles being subject to similar tests under similar conditions, and

transport operators facing similar costs. Coordinating the conditions of access and exchange of vehicle data

at the EU level will not only be more efficient than bilateral agreements and negotiations with individual

manufacturers, but also level the playing field among Member States and put them, collectively, in a

stronger position vis-à-vis the automotive industry.

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BJECTIVES

: W

HAT IS TO BE ACHIEVED

4.1. General objectives

To address the problems identified in section 2 and in line with the overall logic of the Roadworthiness

Package on the one hand, and with the Commission’s strategic priorities on the other hand (‘Vision Zero’

road safety policy framework, the European Green Deal, the Sustainable and Smart Mobility Strategy, the

Zero Pollution Action Plan) and Treaty principles, the general objectives of this revision are to: (i) improve

road safety in the EU; (ii) contribute to sustainable mobility; and (iii) facilitate the free movement of persons

and goods in the EU. Stakeholders were consulted on these objectives as part of public as well as targeted

consultations, including through the Roadworthiness Committee and the Expert Group representing

Member States and industry experts, and a large majority of them agreed with the identified general and

specific objectives (see Annex 2). Improving road safety in the EU and contributing to sustainable mobility

are in line with UN Sustainable Development Goal (SDG) 3 (Ensure healthy lives and promote well-being

for all at all ages), including targets 3.6 (halving the number of deaths and injuries from road traffic

accidents) and 3.9 (by 2030, substantially reduce the number of deaths and illnesses from hazardous

chemicals and air, water and soil pollution and contamination), notably through specific objectives 1 and 2

mentioned below.

4.2. Specific objectives

The specific objectives of the initiative are designed to address the problems and problem drivers described

above (Figure 4). As each of the specific objectives address two or three problem drivers, they complement

each other to help achieve the general objectives. Both SO1 and SO3 contribute to SO2, while there are no

trade-offs between them.

Figure 4: Correspondence between problem drivers and the objectives

SO1: Ensure the adequacy, consistency, objectivity, and quality of roadworthiness testing of today's and

tomorrow's vehicles.

This objective aims to address the challenges presented by the need to test the latest

and emerging vehicle technologies in a coherent manner. More specifically, the testing of EVs and ADAS

must be ensured before most of the new vehicles equipped with such systems are due for their first PTI

(PD1)

115

. To correct for the inability of existing emission tests to identify high-emitting vehicles (PD2),

115

While many electric vehicles are already on the roads, many more new vehicles equipped with ADAS will be due for

PTI in 2026.

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newly developed test methods need to be incorporated in the minimum requirements. Similarly, measures

need to be taken to improve the detection rate of defective or tampered, thus polluting, excessively noisy

and potentially dangerous vehicles (PD3). Some of those vehicles are not tested today, or not frequently

enough to detect those deficiencies (PD5). The majority of stakeholders participating in the targeted

consultation (64 out of 67) agreed with this specific objective. Adapting testing to today's and tomorrow's

vehicles (SO1) will also help achieve SO2.

SO2: Significantly reduce fraud and tampering, and improve the detection of defective vehicles.

This

objective aims to significantly reduce tampering and improve the detection of vehicles with deficiencies, to

allow for the detection of defective/tampered safety and emission (i.e., air pollution and noise emission)

control systems, as well as of odometer fraud, by improving the suitability of emission testing (PD2),

providing for better tools to detect safety-related modifications, notably of vehicle software (PD3), and by

more and targeted inspections (PD5). Most stakeholders participating in the targeted consultation (60 out of

66) agreed with this specific objective.

SO3: Improve electronic storage and exchange of relevant vehicle identification and status data.

This

objective aims at improving electronic storage and exchange of specific vehicle data, therefore addressing

the problem of insufficient availability of such data and mutual recognition by enforcing authorities

(registration, PTI, RSI) (PD4). More accurate status data (such as mileage) and efficient exchange of

information among Member States will also help identify vehicles with tampered odometer (PD3). As such,

SO3 also complements SO2. The majority of stakeholders participating in the targeted consultation (54 out

of 61) agreed with this specific objective.

HAT ARE THE AVAILABLE POLICY OPTIONS

5.1. What is the baseline from which options are assessed?

The EU Reference scenario 2020 is the starting point for the impact assessment of this initiative. The

REF2020 takes into account the impacts of the COVID-19 pandemic that had a significant impact on the

transport sector. More detailed information about the preparation process, assumptions, and results are

included in the Reference scenario publication

116

. Building on REF2020, the baseline has been designed to

include the initiatives of the ‘Fit for 55’ package proposed by the Commission on 14 July 2021

117

and the

initiatives of the RePowerEU package proposed by the Commission on 18 May 2022

118

. The baseline

scenario factors in the revision of the HDV CO

standards Regulation

119

and the new Euro 7 standards

120

the proposed end-of-life vehicles (ELV) Regulation

121

and the forthcoming initiative on fair and non-

discriminatory access to in-vehicle data

122

, as well as other initiatives part of the Road Safety package

123

and the Greening Freight package

124

116

117

EU Reference Scenario 2020 (europa.eu)

https://ec.europa.eu/info/strategy/priorities-2019-2024/european-green-deal/delivering-european-green-deal_en

118

https://ec.europa.eu/commission/presscorner/detail/en/IP_22_3131

119

Regulation (EU) 2024/1610

120

COM(2022) 586 final

121

The proposed ELV Regulation calls for data related to the reasons of deregistering vehicles to be recorded in the

national vehicle registers. See:

https://eur-lex.europa.eu/legal-content/EN/TXT/?uri=CELEX%3A52023PC0451

122

According to current plans, the proposal on access to in-vehicle data would provide for non-discriminatory access to

such data in a harmonised, machine-readable format. This will be key for vehicle inspection too, without, however,

specifying the means of data access, which will continue to allow manufacturers to set their own (often cumbersome)

rules.

123

Proposal for a Directive amending the Driving Licence Directive, proposal for a Directive amending the Cross-Border

Enforcement Directive and proposal for a Directive on the Union-wide effect of certain driving disqualifications.

124

Green Deal: Greening freight for more economic gain with less environmental impact (europa.eu)

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The baseline scenario assumes no further EU level intervention beyond the current Roadworthiness Package

(i.e., the PTI and the RSI Directives as amended by the delegated Regulations to align with the evolution of

type-approval legislation

125

and to introduce the testing of eCall at PTI

126

, and the VRD Directive as last

amended by the revision of the Eurovignette Directive

127

). As some of the provisions of the RWP allowed

for a very long transition period

128

, certain Member States are still notifying transposition measures to the

Commission. The baseline scenario assumes full transposition of the current Roadworthiness Package. In

addition, the baseline reflects the introduction of PN measurement by three Member States

129

The baseline also incorporates

foresight megatrends

and developments captured in the 2022 Strategic

Foresight Report

130

, as explained in section 2.3. Among others, it captures the trend of increasing demand

for transport as population and living standards grow, as well as the links between the digital and green

transition, and the accelerating technological change and hyperconnectivity. In particular, the projected

transport activity draws on the long-term population projections from Eurostat and GDP growth from the

Ageing Report 2021

131

by the Directorate General for Economic and Financial Affairs.

In the baseline scenario, EU transport activity is projected to grow post-2020, following the recovery from

the COVID-19 pandemic. Road transport would maintain its dominant role within the EU by 2050. Road

passenger transport activity (expressed in passenger-kilometres)

132

is projected to grow by 10% between

2015 and 2030 (27% for 2015-2050), while road freight transport activity (expressed in tonne-kilometres)

133

by 27% during 2015-2030 (52% for 2015-2050). Rail transport activity is projected to grow significantly

faster than for road, driven in particular by the completion of the TEN-T core network by 2030 and of the

comprehensive network by 2050, supported by the CEF, Cohesion Fund and ERDF funding, but also by

measures of the ‘Fit for 55’ package

134

and the Greening Freight package. Passenger rail activity is projected

to go up by 37% by 2030 relative to 2015 (86% for 2015-2050). Freight rail traffic would increase by 50%

by 2030 relative to 2015 (107% for 2015-2050).

The share of zero-emission vehicles in the light duty vehicle fleet (passenger cars and light commercial

vehicles) is projected at 15% in 2030, going up to 95% in 2050 in the baseline scenario, while for heavy

duty vehicle fleet (buses and coaches, and heavy goods vehicles) at 6% in 2030 and 72% in 2050. These

developments are driven by the CO

standards Regulations, supported by the Alternative Fuels

Infrastructure Regulation. The current limitations of the emission testing methods applied under the PTI and

RSI Directives are expected to persist in the baseline scenario, with the shares of high-emitting vehicles

135

in the Euro 5/V and Euro 6/VI fleet remaining largely the same. On the other hand, the share of high-

emitting vehicles in the Euro 7 fleet is expected to be lower than for Euro 5/V and Euro 6/VI. The uptake

of zero-emission vehicles, the penetration of Euro 7 vehicles in the fleet and the related introduction of on-

125

126

https://eur-lex.europa.eu/eli/dir_del/2021/1717/oj

and

https://eur-lex.europa.eu/eli/dir_del/2021/1716/oj

https://eur-lex.europa.eu/eli/reg/2015/758/oj

127

Directive (EU) 2022/362 amending Directives 1999/62/EC, 1999/37/EC and (EU) 2019/520, as regards the charging

of vehicles for the use of certain infrastructures,

https://eur-lex.europa.eu/eli/dir/2022/362/oj

128

For example, PTI for motorcycles (with a possibility for exemptions) since January 2022; the deadline to equip all test

centres with all the required equipment was 20 May 2023 (five years after the date of application).

129

Belgium, Germany and the Netherlands.

130

COM(2022) 289 final.

131

The 2021 Ageing Report. Economic and Budgetary Projections for the EU Member States (2019-2070) (europa.eu)

132

Covering passenger cars, buses and coaches, and power-two wheelers.

133

Covering heavy goods vehicles and light commercial vehicles.

134

These measures increase to some extent the competitiveness of rail relative to road and air transport.

135

High emitters are vehicles with defective emission or noise control systems or vehicles with tampered emissions/noise

control systems.

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board emissions monitoring systems

136

, combined, are expected to result in significant reductions of air

pollution emissions from road transport in the baseline scenario. NOx emissions are projected to reduce by

52% in 2030 relative to 2015 (98% reduction for 2015-2050), while particulate matter (PM2.5) emissions

would decrease by 43% in 2030 relative to 2015 (98% reduction for 2015-2050). CO

emissions from road

transport are projected to decrease by 32% by 2030 relative to 2015, and be close to zero by 2050, thanks

to the large-scale uptake of zero-emission vehicles and some use of renewable and low-emission fuels.

In the baseline scenario, the number of fatalities is projected to decrease by 24% by 2030 relative to 2015

and by 31% by 2050 relative to 2015

137

. The number of serious and slight injuries is projected to decrease

by 19% between 2015 and 2030 and by 26% for 2015-2050. This is despite the increase in traffic over time.

Relative to 2019, the number of fatalities would decrease by 15% by 2030 and 23% by 2050, and the number

of serious injuries by 10% by 2030 and 18% by 2050. Thus, the targets of the EU Road Safety Policy

Framework 2021-2030 – Next steps towards “Vision Zero”, of reducing the number of road deaths and the

number of serious injuries by 50% between 2019 and 2030, would not be met. In addition, this is still far

from the goal of the Sustainable and Smart Mobility Strategy of a close to zero death toll for all modes of

transport in the EU by 2050. The external costs of noise emissions are projected to increase by 7% by 2030

relative to 2015 and to remain relatively stable post-2030. The uptake of zero-emission vehicles

compensates to some extent the increase in noise due to the higher traffic

138

In the baseline scenario, the number of periodic technical inspections (PTI) for cars, vans, buses, trucks and

motorcycles is projected to increase from 151.5 million in 2015 to 168.9 million in 2030 and 192.3 million

in 2050

139

. For O1 and O2 vehicles the number of inspections is projected at 7.9 million in 2030 and 8.7

million in 2050. Most of the technologies required for more advanced testing included in the policy

measures are available and part of the baseline; however certain test methods need to be developed. More

detailed explanations are provided in Annex 4 (section 8).

The number of national second-hand vehicle sales with mileage fraud at EU level is projected at 1.71 million

in 2030 and 1.90 million in 2050, and that of cross border vehicle sales with mileage fraud at 3.35 million

in 2030 and 3.64 million in 2050. The national and cross-border odometer fraud is estimated to lead to

damages for European consumers estimated at EUR 10.7 billion in 2030 and EUR 11.7 billion in 2050

140

Expressed as present value over 2026-2050 this amounts to EUR 194.6 billion. More details on the baseline

scenario are provided in Annex 4 (section 2).

Considering the expected effects of the Euro 7 based on the Commission’s proposal, the currently dominant Euro 5/V

and 6/VI vehicles should be gradually replaced by new ones complying with the Euro 7 standard. This would result in

reduced levels of tampering and lower emissions, in particular for heavy-duty vehicles. A limitation to mention here is

that the baseline reflects the Commission proposal. Following the changes agreed by the co-legislators, the baseline likely

overestimates the reduction in the air pollution emissions over time and thus slightly underestimates the contribution of

this initiative to the air pollution emissions reduction. This is particularly relevant in the short to medium term. In the

medium to long term this is less relevant due to the expected large-scale penetration of the zero-emission vehicles in the

fleet.

137

Projections refer to injuries in accidents in which a car, a van, a bus or a truck, or a motorcycle is involved.

138

It should however be noted that the reduction in noise due to zero-emission vehicles is only linked to the powertrain.

The noise from tyres still remains.

139

They are derived based on the ‘testing frequency’ and the average number of PTIs in the statistical life of a vehicle.

140

The average cost of mileage fraud, due to higher purchase price and maintenance costs incurred, is estimated at EUR

2,119 per vehicle in 2022 prices drawing on a Belgian Car-Pass study (https://www.car-

pass.be/files/article_files/file/7/crm%2520study%2520final%2520report.pdf).

More explanations are provided in section

2 of Annex 4.

136

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5.2. Description of the policy options

As a first step, a comprehensive list of possible policy measures was established after extensive

consultations with stakeholders, expert meetings, and independent research in the context of the impact

assessment support study and the Commission’s own analysis. This list was subsequently screened based

on the likely effectiveness, efficiency and proportionality of the proposed measures in relation to the given

objectives, as well as their legal, political and technical feasibility.

Discarded policy measures and policy options

The possibility to adopt further recommendations or a communication from the Commission was discarded

at early stage as non-regulatory measures could not be sufficiently effective in addressing the problems

identified and would have limited effect on harmonisation. Most stakeholders, including public authorities

participating in the open public consultation, agree that a legislative review of the RWP would be more

effective (see Annex 2). Out of the more than 40 policy measures discussed at five meetings with the Expert

Group on Roadworthiness and vehicle registration documents (RWEG), 13 measures have been discarded.

A more detailed list with all discarded measures can be found in Annex 8.

Retained policy measures and policy options

A list of 26 policy measures has been retained. Table 3 presents an overview of the policy measures

included in the policy options and their links with the specific objectives. A detailed description of the policy

measures is provided in Annex 7.

The policy options offer choices with focus on different aspects such as means of testing (e.g., PTI vs

roadside inspections, tailpipe testing only vs its combination with remote sensing) or different levels of

harmonisation in the exchange of vehicle data, the scope and methods of testing and the mutual recognition

of PTI certificates.

Four policy options have been identified (PO1a, PO1b, PO2 and PO3), and each of the four policy options

includes a set of policy measures that are common for all options, as well as additional measures that are

included in one or more options. The common set of policy measures (from PMC1 to PMC9) are considered

as the minimum necessary to correct the shortcomings of the existing RWP Directives and to adapt to

technological and regulatory developments over the last ten years, and are supported by most

stakeholders. Beyond the common measures, PO1a and PO1b differ in their focus, while compared

to them PO2 and PO3 represent an increasing level of ambition and harmonisation. This reflects the

preferences of various stakeholder groups and genuine options for more or less convergence in the

areas covered by the three Directives.

Table 3: Policy measures and policy options

PM#

Policy Measure

Specific

objective

PO1a

PO1b

PO2

PO3

Measures common to all policy options

New PTI and RSI tests

PMC1

Adapt PTI to electric and hybrid vehicles (safety,

environmental performance, standardised data), including

training of inspectors

Update PTI and RSI due to new requirements in the

General Safety Regulation and checking emission

reduction systems (new test items, including checks of

software status/integrity), by reading on-board diagnostics

SO1

PMC2

SO1

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PM#

PMC3

Policy Measure

Mandatory PN testing of LDVs and HDVs equipped with

particle filter, at PTI, and of HDVs at technical roadside

inspections of commercial vehicles

Mandatory NOx testing of LDV and HDV at PTI, and

HDVs at roadside inspections

Frequency of testing

Mandatory roadworthiness testing following significant

modifications of the vehicle (e.g. change of class,

propulsion system)

Facilitating exchange of PTI and registration data

Require roadworthiness certificate in electronic format

only

Provide electronic access to relevant data, including on

PTI reports stored in national databases, to the registration

authorities of other Member States using a common

interface

Harmonisation and regular update of the technical data in

the vehicle registration documents (of currently optional

content)

Tackling odometer tampering

Member States to record odometer readings in a national

database and make the records available to other MSs in

the case of re-registration

Scope of vehicles subject to PTI/RSI

Specific

objective

SO1,

SO2

SO1,

SO2

PO1a

PO1b

PO2

PO3

PMC4

PMC5

PMC6

PMC7

SO3

PMC8

SO3

PMC9

SO2,

SO3

Measures not included in all policy options

PM1

RSI for heavy/powerful motorcycles (L category >

125cm3) as an alternative measure, in Member States

where they are not subject to PTI (i.e., using the available

opt-out)

Mandatory PTI for motorcycles above 125cm3 (remove

opt-out)

Extend PTI to all motorcycles (incl. from 50cm3 = all L3e,

L4e), plus tricycles (L5e) and heavy quadricycles (L7e)

Mandatory PTI for light trailers (O1 and O2 categories)

Frequency of testing

PM5

PM6

Annual emission testing for light commercial vehicles

(N1) instead of the currently required 4-2-2- frequency

Mandatory yearly testing for vehicles that are 10-year-old

or older

Recognition of PTIs conducted in another Member

State

PTI certificate issued in any EU MS is recognised by the

MS of registration + further harmonisation of test methods

PTI certificate issued in any EU MS is recognised by the

MS of registration for a period of up to 6 months (for

passenger cars only), on the condition that the next PTI is

conducted in the MS of registration

PTI in another EU MS recognised by MS of registration

based on bilateral agreement (voluntary recognition)

Improve current PTI tests and procedures

PM10

More advanced testing of noise for motorcycles

SO2

PM2

PM3

PM4

SO2

PM7

PM8

SO1,

SO3

PM9

SO3

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PM#

PM11

Policy Measure

Data governance: further define the procedures and the

means of access to vehicle technical information by

testing centres free of charge

RSI methods

NOx, PM, and noise measurement by remote sensing in

RSI of all vehicles (with option for simplified PTI if

vehicle passed recent RSI)

Mandatory inspection of cargo securing

Scope of vehicles subject to RSI

Specific

objective

SO1,

SO3

PO1a

PO1b

PO2

PO3

PM12

SO1,

SO2

SO1,

SO2

PM13

PM14

PM15

Extend the scope of application of roadside inspections to

light commercial (N1) vehicles

Extend the scope of application of roadside inspections to

2- and 3-wheeled vehicles (L-vehicles from L3)

Registration certificate and registered data

Introduce issuing the registration certificates in digital

format to gradually replace current paper (and smart card)

documents

Add new data to the vehicle register – minimum

mandatory set (including among others: country of 1

registration, registration status, PTI status, changes due to

transformation)

PM16

SO3

PM17

SO3

Adapting PTI to EVs (PMC1) and including new test items through the ePTI (PMC2, including the testing

of software integrity of safety- and emission-relevant systems) will help align the PTI rules with

technological and regulatory developments and hence contribute to SO1

(Ensure the adequacy, consistency,

objectivity, and quality of roadworthiness testing of today's and tomorrow's vehicles).

Similarly, new

emission test methods for both particles and NOx (PMC3 and PMC4) are necessary to adapt to more recent

emission control technologies (contributing to SO1) and to capture high emitting vehicles, including

tampered ones (contributing to SO2). PMC5 will also contribute to SO2

(Significantly reduce fraud and

tampering, and improve the detection of defective vehicles)

by requiring that vehicles undergo a

roadworthiness test following any significant modification involving e.g., the change of the propulsion

system or the emission class. PMC6, PMC7 and PMC8 contribute to SO3

(Improve electronic storage and

facilitating exchange of relevant vehicle identification and status data)

through digitalisation of the

roadworthiness certificate, linking national vehicle registers and extending the set of harmonised vehicle

data in those registers. PMC9 introduces a requirement for Member States to record odometer readings in

national databases and make those records available to other Member States in the case of re-registration.

Garages (including car manufacturers), tyre and other repair services, in addition to PTI bodies would have

to provide such readings for cars and vans following every visit. PMC9 contributes to SO2 and SO3.

Reasoning behind the packaging of options

PO1a

and

PO1b

are designed rather conservatively as regards the scope of vehicles to be tested and

are limited to the measures that are indispensable to address each of the problem drivers and to meet

all specific objectives, while each of these two options has a specific focus: PO1a focuses primarily

on enhancing the exchange of vehicle data and enhancing digitisation. PO1b on the other hand

focuses more on improving the testing of vehicles and introducing additional and more ambitious

measures regarding emission testing and recognition of PTI.

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PO2

is designed to provide a more integrated approach. It builds on the measures already included

in PO1a and PO1b and adds more ambition with additional measures such as the extension of

roadside inspections to vans. It also improves access to relevant technical and registration data

through specific measures, such as better access to vehicle data necessary for testing notably modern

electronic safety systems.

PO3

builds on PO2 and takes its integrated approach, but compared to PO2 it further extends the

scope of vehicles and items to be tested. It further extends the scope of PTIs to cover light trailers

and motorcycles with smaller engine size, combined with mandatory roadside inspection for

motorcycles. It also provides a wider recognition of PTI inspections taking place in other Member

States. Overall, it represents the most ambitious option.

Policy option 1a (PO1a)

This policy option aims primarily at more efficient use of vehicle (registration and status) data, further

focusing on addressing SO3. In addition to the common measures, PO1a would require adding certain new

data elements to national vehicle registers, notably related to the registration and roadworthiness status of

the vehicle, thus facilitating the implementation and enforcement of the RWP as well as that of the ELV

legislation (PM17). Issuing registration certificates in digital format (PM16) will further enhance the

efficiency of data exchange. Furthermore, PO1a would allow Member States to sign bilateral agreements

to enable the cross-border recognition of PTIs and thus facilitate the free movement of people and goods

(PM9). PM9, PM16 and PM17 contribute to addressing SO3.

Beyond the common measures, PO1a applies a relatively light touch approach to addressing SO2. To reduce

the number of tampered and defective motorcycles due to their lack of testing, it would require those

Member State which exempt these vehicles from PTI to apply as alternative measure, testing a share of

them at the roadside (PM1). Most stakeholders, including Member States authorities and especially

EReg/EUCARIS support this policy option, while the PTI sector (CITA and others) and motorcycle

manufacturers (ACEM) would prefer stricter PTI and RSI requirements.

Policy option 1b (PO1b)

Beyond the common measures, PO1b further focuses on addressing SO2 through more effective technical

inspections. The most important measure in this respect is the use of remote sensing technology

141

(PM12),

which allows targeted and thus much more effective and efficient emission testing at the roadside. Remote

sensing, using laser technology (LiDAR) to detect critical pollutants, has been demonstrated to be an

effective method to screen very large numbers of vehicles at relatively low cost

142

. This measure will allow

monitoring the emissions of virtually the entire vehicle fleet, including older vehicles, depending on the

scale of its implementation. Remote sensing using microphones is able to single out unusually noisy

vehicles even in dense traffic

143

. This allows the identification of potentially high-emitting vehicles that can

be either inspected at a subsequent roadside check immediately after being identified or invited to a

roadworthiness centre for an emission test.

In addition, to address specific groups of vehicles that are more prone to tampering or defects than the

average, PO1b introduces specific measures: it would remove the possibility to exempt motorcycles from

PTI (PM2) and require yearly emission testing of light commercial vehicles (PM5). Furthermore, it would

141

142

https://cares-project.eu/about/

See e.g.,

https://publications.tno.nl/publication/34638150/2gBdxC/hooftman-2020-analysis.pdf

and

https://nemo-

cities.eu/remote-sensing/

143

https://nemo-cities.eu/remote-sensing-device-for-noise/

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introduce mandatory annual PTIs for vehicles older than 10 years (PM6), an improved noise test for

motorcycles based on type-approval requirements (PM10) and make the inspection of cargo securing

mandatory (PM13). As such, all these measures go further in addressing SO2 (beyond the common

measures included in all options). PO1b would further facilitate the free movement of people, and further

address SO3, by requiring that the Member State of registration recognises the PTI certificate issued by

another Member State for a period of up to six months, provided that the next PTI is conducted in the

Member State of registration (PM8). This policy option enjoys the support of the PTI industry (CITA, FSD

and others) as well as automobile manufacturers (ACEA), testing equipment (EGEA) and motorcycle

manufacturers (ACEM), while certain Member States and motorcycle users find it too demanding. Stricter

cargo securing requirements are strongly supported by the logistics industry (in particular by EUMOS).

Policy option 2 (PO2)

PO2 combines most of the measures of PO1a and PO1b. As regards the testing of motorcycles, PO2

includes a measure of PO1a (PM1), while for the recognition of PTIs conducted in another Member State,

it uses PM8 (temporary recognition), like in PO1b. To further improve the consistency and quality of testing

of modern vehicles (SO1) and the availability of relevant technical data to testing centres (SO3), it includes

an additional measure on data governance (PM11), aiming to define the procedures and the means of access

to vehicle technical information (including in-vehicle data). The measure would complement an existing

Implementing Regulation

144

and build on the upcoming proposal on access to in-vehicle data

145

To further reduce the number of tampered and defective vehicles and contribute towards SO2, in addition

to the measures of PO1b and PO1a, it would also introduce roadside inspections for light commercial

vehicles (PM14). RSI complements PTI and is arguably better suited to detect and reduce fraud thanks to

the vehicle users having no prior notice of roadside tests, in comparison to pre-planned periodical technical

inspections, where pre- and post-tempering of vehicles cannot be excluded. In addition to being a

combination of PO1a and PO1b, PM11 on data governance makes this policy option more favoured by the

PTI industry (CITA, FSD and others) as well as FIA, testing equipment (EGEA) and motorcycle

manufacturers (ACEM). It is supported also by some Member States, notably those that rely on thousands

of smaller roadworthiness testing centres. On the other hand, the issue of access to vehicle data is considered

less important by automobile manufacturers. Stricter cargo securing requirements included in this option

are strongly supported by the logistics industry (EUMOS).

Policy option 3 (PO3)

PO3 goes further on harmonising the scope and methods of roadworthiness testing and the mutual

recognition of PTI certificates. As such, it aims to further address SO2, as well as SO1 and contributes to

facilitating the free movement of people and goods more comprehensively than the other options also

further addresses SO3. To the measures of PO2, PO3 adds further extension of scope of PTI to cover all

motorcycles without exception (PM3) and light trailers (PM4), and it extends RSI to motorcycles (PM15).

All these measures further contribute to addressing SO2. PO3 is the only option to include PM7, a

requirement that PTI certificates issued in any other EU Member States are recognised by the Member State

of registration without limitations, further addressing SO1 and SO3. This necessitates further harmonisation

of test methods where the PTI Directive currently offers various options. It would thus mean less room for

manoeuvre for Member States, and fewer choices for inspection centres. This being the most ambitious

144

145

https://eur-lex.europa.eu/eli/reg_impl/2019/621/oj

https://ec.europa.eu/info/law/better-regulation/have-your-say/initiatives/13180-Access-to-vehicle-data-functions-

and-resources_en

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option, it is mainly supported by the PTI sector, including equipment manufacturers as well as by ACEM

and a few Member States that apply stricter requirements than the current RWP Directives.

HAT ARE THE IMPACTS OF THE POLICY OPTIONS

This section summarises the main expected economic, social and environmental impacts of each policy

option (PO)

146

. The proposed measures are assumed to be implemented from 2026 onwards, so the

assessment has been undertaken for the 2026-2050 period and refers to EU27. Costs and benefits are

expressed as present value over the 2026-2050 period, using a 3% discount rate, in constant prices of the

year 2022. Further details on the methodological approach are provided in Annex 4. The evidence

underlying the assessment of impacts is based on the best available evidence, including multiple studies

involving scientific research, as well as thorough consultation with experts.

6.1.

Economic impacts

This section focuses on the economic impacts of the policy options on national public authorities, businesses

and citizens. It also provides an assessment of impacts on competitiveness, on innovation and technological

developments, on small and medium enterprises (SMEs), on the functioning of the internal market and

competition, and looks at territorial impacts and digital by default. The assessment of economic impacts

draws on multiple data sources, including the targeted stakeholders’ consultation (interviews and survey)

and OPC, and findings from desk research in the context of the impact assessment support study. The costs

and benefits of each policy measure by stakeholder group are described in detail in Annex 4 (sections 3 and

4), including the assumptions used to estimate them. In addition, the cost-benefit analysis for some key

policy measures is provided in Annex 4 (section 6).

6.1.1. Impacts on national public authorities

All policy options are expected to result in adjustment and administrative costs for national public

authorities, while PO1b and PO3 would also lead to additional enforcement costs. At the same time, all

policy options are expected to result in significant administrative costs savings for the national authorities

(see Table 4 to Table 6). The costs and costs savings by policy option are discussed below, while the detailed

calculations by policy measure are provided in Annex 4 (section 3).

Adjustment costs.

All policy options include adjustment costs related to three common measures (PMC2,

PMC3 and PMC4). They cover one-off adjustment costs (see Table 6) for: the acquisition of on-board

diagnostic (OBD) scanning tools for RSI and the training of inspectors to use the OBD tools

147

(PMC2),

estimated at EUR 0.2 million in 2026 relative to the baseline; the purchase of PN measurement devices for

RIS and the training of inspectors to use them

148

(PMC3), estimated at EUR 0.7 million in 2026; and, the

acquisition of NOx measurement devices for RIS and the training of inspectors

149

(PMC4), amounting to

EUR 2 million. In addition, recurrent adjustment costs (i.e., maintenance and calibration costs) for the PN

and NOx measurement devices are assumed at 5% of the capital costs, based on stakeholders’ feedback,

and are estimated at EUR 32,750 per year from 2026 onwards in PMC3 and at EUR 98,250 per year in

146

The analysis in this section is based on Ricardo et al. (2024), Impact assessment support study on the directives of the

roadworthiness package, Contract no. MOVE/C2/SER/2022-583/SI2.895928, under FWC no. MOVE/2022/OP/0001,

and on the analysis of stakeholders' feedback.

147

The costs are estimated at EUR 1,000 per tool. One tool is required per RSI unit, and the number of RSI units total

131 at EU level. Two hours of training are assumed for each of the 393 RSI inspectors across EU27.

148

One PN measurement device is needed per RSI unit, at a cost of EUR 5,000 each. 131 RSI units would need to

purchase PN testing equipment. An additional half-day of training related to the use of PN measurement devices is

assumed for the estimated 393 RSI inspectors across the EU in 2026.

149

One NOx measurement device is assumed per RSI unit, at a cost of EUR 15,000 each. 131 RSI units would need to

purchase the equipment. An additional half-day of training is assumed for the 393 RSI inspectors.

kom (2025) 0180 - Ingen titel

PMC4 (see Table 5). Expressed as present value over 2026-2050, the total one-off and recurrent adjustment

costs are estimated at EUR 0.2 million for PMC2, EUR 1.3 million for PMC3 and EUR 3.8 million for

PMC4 (see Table 4). Thus, the adjustment costs due to the common set of measures (PMC2, PMC3 and

PMC4) are estimated at around EUR 5.2 million, of which EUR 2.9 million one-off costs. In addition to the

common measures, the most significant one-off adjustment costs in

PO1a

are due to PM9, concerning the

recognition of PTIs conducted in another Member State than that of registration based on bilateral

agreements. National authorities are expected to incur expenses for establishing bilateral agreements and

implementing procedures to facilitate inspections in another Member State. Assuming each Member State

establishes three bilateral agreements, the total costs for 41 such agreements have been estimated at around

EUR 1.4 million in 2026 (EUR 53,550 per Member State). In addition, PM1 will require that those Member

States

150

that do not have a PTI requirement for motorcycles to introduce roadside inspections for

motorcycles over 125cm3 as an alternative, leading to the need of purchasing additional equipment to

support these inspections (one-off adjustment costs) and of maintaining it (recurrent adjustment costs). The

one-off adjustment costs due to PM1 are estimated at EUR 0.1 million in 2026 and the recurrent adjustment

costs at EUR 12,000 per year from 2026 onwards

151

(see Table 5 and Table 6). The total one-off and

recurrent adjustment costs for national public authorities due to PO1a are thus estimated at

EUR 7 million

(see Table 4), expressed as present value over 2026-2050, of which EUR 4.4 million one-off costs.

PO1b,

in addition to the costs of the common measures (PMC2, PMC3 and PMC4), the most significant

additional adjustment costs for authorities arise due to the introduction of remote sensing, and the option to

use plume chasing to measure NOx emissions from trucks, as well as the installation of noise cameras

(PM12). PM12 involves one-off costs for the purchase of the necessary equipment, the setting up of the

corresponding IT infrastructure and related training of inspectors, as well as recurrent costs for the

maintenance of the equipment and data management, and labour costs for the inspectors performing the

plume chasing

152

. The one-off adjustment costs due to PM12 amount to EUR 23.6 million in 2026, and the

recurrent adjustment costs to EUR 9.4 million per year (see Table 5 and Table 6). Total adjustment costs

due to this measure are thus estimated at EUR 192.9 million, expressed as present value over 2026-2050

relative to the baseline. In addition, PM13 is expected to lead to one-off adjustment costs for national public

authorities for training on cargo securing in the 14 Member States

153

that currently do not require minimum

training of inspectors (EUR 26,916 in 2026), and recurrent adjustment costs for the retraining of inspectors

on a biennial basis (EUR 26,916 per year every second year after 2026)

154

. Total adjustment costs for PO1b

are thus estimated at

EUR 198.3 million

(see Table 4), expressed as present value over the 2026-2050

period relative to the baseline, of which EUR 26.5 million one-off costs.

PO2

includes the adjustment costs related to the common measures (PMC2, PMC3, PMC4), the costs

150

These are: BE, FI, IE, NL, MT and PT. FR will introduce PTI for powered two- and three-wheelers and quadricycles in

2024. DK does not have mandatory PTI but since 1 January 2022 it has introduced roadside inspections. In the case of

PT, current requirements cover only motorcycles over 250cc.

151

For a 5% share of the motorcycles fleet one extra RSI unit per Member State is expected to be sufficient. The capital

costs are estimated at EUR 20,000 per unit and maintenance costs are assumed at around 10% of the capital costs.

152

For

remote sensing,

250 devices would be needed in EU27 to be able to analyse at least 30% of the road fleet. The

capital cost of a remote sensing equipment is estimated at EUR 85,000. Maintenance and calibration costs are around 5%

of the capital costs, and the cost for the processing and data management EUR 24,000 per year per device. In addition,

one day of training for the use of NOx and PM remote sensing equipment is assumed for the 393 RSI inspectors. For

plume chasing,

the capital costs are estimated at EUR 32,500 per equipment. On average, two vehicles are assumed per

Member State, for 26 Member States (DK has already implemented the system). The maintenance and calibration costs

are around 5% of the capital cost. Labour costs are estimated assuming one inspector per plume chasing vehicle and four

days per week of plume chasing. Two days of training on plume chasing are assumed for the 52 inspectors. For

acoustic

cameras,

the capital costs are estimated at EUR 2,000 per device, and the maintenance cost at 5% of the capital cost. A

half-day training would be needed for 393 RSI inspectors, for using the acoustic cameras.

153

BE, DK, DE, EE, FR, IE, LV, LU, BG, FI, IT, NL, PL and PT.

154

Training for cargo securing is assumed to take 3 hours, with 264 roadside inspectors requiring training.

kom (2025) 0180 - Ingen titel

related to PM1 as in PO1a, and the costs related to PM12 and PM13 as in PO1b. To this, PO2 adds one-off

costs for additional roadside equipment and training of inspectors due to the introduction of roadside

inspections for light commercial vehicles (PM14)

155

, estimated at EUR 3.1 million in 2026, and recurrent

costs for the maintenance of equipment, estimated at EUR 0.3 million per year

156

(see Table 5 and Table

6). Expressed as present value over 2026-2050, the total costs of PM14 are estimated at EUR 8.6 million.

Total adjustment costs for PO2 are thus estimated at

EUR 207.2 million,

expressed as present value over

2026-2050 relative to the baseline, of which EUR 29.7 million one-off costs.

PO3

includes the adjustment costs related to the common measures (PMC2, PMC3, PMC4) and the costs

related to PM12, PM13 and PM14 as in PO2. Moreover, it adds one-off adjustment costs for the purchase

of additional mobile inspection units due to the introduction of roadside checks for motorcycles (PM15)

157

estimated at EUR 0.4 million in 2026, and recurrent costs for the maintenance of the inspection units (EUR

40,000 per year from 2026 onwards)

158

. Expressed as present value over 2026-2050, the total costs of PM15

are estimated at EUR 1.1 million. Thus, the total adjustment costs for authorities for PO3 are estimated at

EUR 208 million,

expressed as present value over 2026-2050 relative to the baseline, of which EUR 30

million one-off costs.

Administrative costs.

All policy options include administrative costs for public authorities related to four

common measures (PMC6, PMC7, PMC8 and PMC9). The digitalisation of the roadworthiness certificate

(PMC6) is expected to lead to one-off administrative costs for the development of the software for electronic

certificates, estimated at EUR 17.8 million in 2026

159

, and recurrent administrative costs for the

maintenance and update of the system (EUR 0.9 million per year from 2026 onwards)

160

. The

interconnection of national vehicle registers (PMC7) would result in one-off administrative costs for

developing the common interfaces for accessing the data, estimated at EUR 8.1 million in 2026 (EUR

300,000 per Member State), and recurrent administrative costs for providing access to the relevant data

(EUR 0.4 million per year from 2026 onwards). Further harmonisation and regular update of technical data

in the registration documents (PMC8) is expected to lead to one-off administrative costs for redesigning

and setting up the new template for the registration documents, estimated at EUR 0.7 million in 2026 and

recurrent administrative costs for the regular update of the vehicle registration documents with new items

that may be found relevant in the future (EUR 0.5 million per year from 2026 onwards). The most significant

administrative costs in all policy options arise from PMC9, under which authorities (except Belgium and

the Netherlands that have already implemented the system) will need to develop a system for the recording

of odometer readings of vehicles at garages and other repair stations. Based on the information provided by

CAR-Pass

161

, the one-off cost per database that will be collecting the odometer readings at Member State

155

Few Member States (ES, HU, SE, SK and FI) already conduct roadside inspections for light commercial vehicles.

This measure is thus relevant for 22 MS.

156

The extra inspections will be delivered by an estimated total of 182 inspectors in around 61 roadside inspection units.

These units will need to be equipped with relevant equipment. The one-off cost of the roadside equipment is around EUR

50,000, and the maintenance cost is estimated at 10% of the capital cost. One-day training per inspector is assumed.

157

Few Member States (SE, SI, AT, FI, DK, HU, RO) already perform such inspections and are thus part of the baseline.

158

On the basis of the additional number of inspections to be conducted it is estimated that a total of 32 inspectors will

be needed for the 20 Member States. With an average of 3 inspectors per unit, each Member State will need a minimum

of one additional set of roadside equipment for testing of motorcycles. The one-off cost per equipment is estimated at

EUR 20,000, and the recurrent maintenance cost at 10% of the initial cost. In addition, a one-day training is assumed per

inspector in 2026 for the 32 inspectors.

159

Assuming one-off costs of EUR 500,000 per IT system for each of the 15 Member States with smaller volumes of

inspections (BG, CY, EE, FI, HR, HU, IE, LT, LV, LU, MT, SI, SK, DK and CZ ), EUR 750,000 per IT system for each

of the 7 Member States with medium volumes of inspections (AT, BE, EL, NL, PT, RO and SE) and EUR 1,000,000 per

IT system for each of the 5 Member States with higher volumes of inspections (DE, FR, IT, PL and ES). More details are

provided in Annex 4 (section 3).

160

Assumed at 5% of the capital costs.

161

https://www.car-pass.be/en/

kom (2025) 0180 - Ingen titel

level is estimated at around EUR 1 million. Furthermore, the annual cost of operating the system was

estimated at around EUR 0.42 per vehicle (in 2022 prices)

162

. In total, one-off administrative costs for

authorities are estimated at around EUR 25 million in 2026, and recurrent costs at EUR 111.4 million in

2030 and EUR 125.6 million in 2050 relative to the baseline

163

. Expressed as present value over 2026-2050,

the total one-off and recurrent administrative costs are estimated at EUR 33.7 million for PMC6, EUR 15.4

million for PMC7, EUR 9.4 million for PMC8 and EUR 2.12 billion for PMC9 (see Table 4). Thus, the

administrative costs due to the common set of measures (PMC6, PMC7, PMC8 and PMC9) are estimated

at around EUR 2.18 billion, expressed as present value over 2026-2050, of which EUR 51.6 million one-

off costs.

PO1a,

beyond the costs of the common measures (PMC6, PMC7, PMC8 and PMC9), additional

administrative costs are expected from the introduction of RSI for motorcycles not covered by PTI in six

Member States (PM1), from the digitalisation of the registration certificates (PM16), and from adding new

data elements to the vehicle registers (PM17). The recurrent administrative costs (i.e., labour costs for the

additional inspections) due to PM1 are estimated at EUR 0.5 million in 2030 and EUR 0.6 million in 2050

relative to the baseline

164

. For PM16, the one-off costs for the adaptation of the IT system are estimated at

EUR 12.8 million in 2026, while the recurrent costs for maintenance are estimated at EUR 1.3 million per

year

165

. The one-off costs for harmonising the dataset in PM17 are estimated at EUR 0.5 million in 2026

and the recurrent costs for continuous data updates and broader maintenance of the dataset at EUR 0.4

million per year. Expressed as present value over 2026-2050, total administrative costs are estimated at

EUR 9.1 million for PM1, EUR 35.8 million for PM16 and EUR 8.4 million for PM17. Altogether, the

administrative costs for authorities under PO1a amount to

EUR 2.23 billion

expressed as present value over

2026-2050 relative to the baseline.

On top of the common measures,

PO1b

includes only one measure that generates administrative costs for

authorities, namely the mandatory inspection of cargo securing (PM13). The recurrent administrative costs

relate to labour costs for the additional cargo securing inspections and are estimated at EUR 0.5

million in 2030 and EUR 0.6 million in 2050 relative to the baseline

166

(EUR 9.8 million expressed as

present value over 2026-2050). The total administrative costs for authorities under PO1b are thus estimated

EUR 2.19 billion,

expressed as present value over 2026-2050.

PO2

includes the administrative costs related to the common measures, the costs related to PM1, PM16 and

PM17 as in PO1a, and the costs related to PM13 as in PO1b. In addition, it includes administrative costs

related to two other measures (PM11 and PM14). In the case of PM11 (adaptations related to data

governance ensuring access to vehicle data for PTI centres), total one-off costs for the adaptation of the IT

system are estimated at EUR 13 million in 2026

167

, and recurrent administrative costs at EUR 1.3 million

per year

168

. This is equivalent to total one-off and recurrent costs of EUR 36.3 million, expressed as present

value over 2026-2050. In addition, the roadside testing of vans (PM14) will also generate recurrent

administrative costs (i.e., labour costs for the additional inspections), estimated at EUR 5.6 million in 2030

162

European Parliament (2018), Odometer Manipulation in motor vehicles in Europe,

https://www.europarl.europa.eu/RegData/etudes/STUD/2018/615637/EPRS_STU%282018%29615637_EN.pdf

163

The number of cars and vans relevant for PMC9 are projected at 262.4 million in 2030 and 295.8 million in 2050.

164

The average cost per inspection is estimated at EUR 5.7 and the number of roadside inspections for motorcycles in

PM1 at 82,566 in 2030 and 104,321 in 2050 for the 6 Member States concerned (BE, FI, IE, NL, MT and PT).

165

The one-off costs for the adaptation of the IT system are estimated at EUR 300,000 to EUR 1,000,000 per MS,

depending on the volume of new registrations, and costs for maintenance at 10% of the capital costs.

166

A cargo securing inspection takes on average 20 minutes. Cargo securing inspections are expected to cover 5% of the

N2/N3 fleet in the Member States affected by the measure (EE, FR, IE, LV and LU).

167

Inputs from stakeholders (NL and SI authorities) suggest one-off costs for the adaptation of IT systems in the range of EUR

300,000 to EUR 1,000,000 per country, depending on the volume of PTI inspections per country.

168

Recurrent administrative costs for maintenance are estimated at around 10% of the capital costs.

kom (2025) 0180 - Ingen titel

and EUR 6.7 million in 2050

169

relative to the baseline (EUR 107.5 million, expressed as present value over

2026-2050). All in all, the one-off and recurrent administrative costs for authorities under PO2 are expected

to amount to

EUR 2.39 billion,

expressed as present value over 2026-2050.

PO3

includes the administrative costs related to the common measures and the costs related to the additional

measures under PO2 (except for PM1). In addition, the introduction of RSI for motorcycles (PM15) is

expected to lead to recurrent administrative costs (i.e., labour costs for the additional inspections), estimated

at EUR 1 million in 2030 and EUR 1.3 million in 2050

170

(EUR 19.5 million expressed as present value

over 2026-2050). Thus, the total one-off and recurrent administrative costs for authorities due to PO3 would

be close to

EUR 2.40 billion,

expressed as present value over 2026-2050 relative to the baseline.

Enforcement costs.

No enforcement costs for national authorities are expected in PO1a and PO2. In

PO1b

recurrent enforcement costs are due to the introduction of mandatory PTI for motorcycles above 125cm3

(PM2) that will imply some extra costs for the authorities that are responsible for monitoring the operation

of the system, for evaluating the quality and impartiality of the additional tests. Recurrent enforcement costs

in PO1b are estimated at EUR 1.7 million in 2030 and EUR 2.1 million in 2050

171

(see Table 5), or

EUR

32.9 million

expressed as present value over 2026-2050 relative to the baseline. Similarly, in

PO3,

the

extended scope of PTI to all motorcycles (PM3) is expected to result in monitoring costs of EUR 2 million

in 2030 and EUR 2.5 million in 2050 (EUR 38.1 million expressed as present value over 2026-2050) and

the mandatory PTI for light trailers (PM4) will lead to monitoring costs of EUR 2.1 million in 2030 and

EUR 2.3 million in 2050

172

(EUR 39.2 million expressed as present value over 2026-2050). Total recurrent

enforcement costs for PO3 are thus estimated at

EUR 77.4 million,

expressed as present value over 2026-

2050 (see Table 4).

Administrative cost savings.

Recurrent cost savings for national administrations arise from the common

measures PMC6 (roadworthiness certificate in electronic format) and PMC7 (the interlinking of national

vehicle registers) in all policy options, as well as from PM16 (issuing digital registration certificates)

included in PO1a, PO2 and PO3. The savings are expected to be significant in all options, and especially

under

PO1a, PO2 and PO3,

reaching

EUR 5.23 billion,

expressed as present value over 2026-2050 (see

Table 4). In

PO1b

they are estimated to be lower, at

EUR 3.80 billion.

The largest potential savings are

expected from PMC6, due to issuing the roadworthiness certificates in electronic format only, estimated at

EUR 167.3 million in 2030 and EUR 190.6 million in 2050 (EUR 3.16 billion expressed as present value

over 2026-2050)

173

. Cost savings related to PMC7, due to the time saved for the re-registration of a vehicle

in another Member State, are estimated at EUR 35.8 million per year from 2026 onwards (EUR 641.8

million expressed as present value over 2026-2050)

174

. In addition, PM16 will bring further recurrent

administrative costs savings for national public authorities, by avoiding the costs of printing, distribution

and handling of paper/plastic registration certificates, estimated at EUR 79.3 million in 2030 and EUR 86.3

169

The additional number of inspections due to the measures is estimated at 497,627 in 2030 and 588,721 in 2050. The

cost per inspection is estimated at EUR 11.3.

170

For the 20 Member States concerned (excluding SE, SI, AT, FI, DK, HU, RO that already perform such inspections)

the number of additional inspections is estimated at 176,228 in 2030 and 227,291 in 2050 relative to the baseline. The

cost per inspection is estimated at EUR 5.7.

171

An average monitoring cost of EUR 2.25 per PTI for motorcycles.

172

An average monitoring cost of EUR 1.5 per PTI for light trailers.

173

The cost of a paper roadworthiness (RW) certificate is estimated at 1 EUR per certificate. The number of RW

certificates issued in paper format in the baseline is estimated at 167.3 million in 2030 and 190.6 million in 2050.

174

PMC7 is expected to lead to time savings of around 15 minutes per re-registration of a vehicle in another Member

State because of less need of reaching out to other National Contact Points by phone/mail.

kom (2025) 0180 - Ingen titel

million in 2050 (EUR 1.43 billion expressed as present value over 2026-2050)

175

Net benefits.

All policy options are expected to lead to net benefits for national public authorities. Net

benefits, expressed as present value over 2026-2050 relative to the baseline, are estimated to be the highest

in PO1a (EUR 2.99 billion), followed by PO2 (EUR 2.63 billion), PO3 (EUR 2.54 billion) and PO1b (EUR

1.38 billion).

Table 4: Recurrent and one-off costs, and costs savings for national public authorities in the policy options,

expressed as present value over 2026-2050 relative to the baseline, in million EUR (2022 prices)

PO1a

Adjustment costs

PMC2

PMC3

PMC4

PM1

PM9

PM12

PM13

PM14

PM15

Administrative costs

PMC6

PMC7

PMC8

PMC9

PM1

PM11

PM13

PM14

PM15

PM16

PM17

Enforcement costs

PM2

PM3

PM4

Administrative costs savings

PMC6

PMC7

PM16

Net benefits

7.0

0.2

1.3

3.8

0.3

1.4

Difference to the baseline

PO1b

PO2

198.3

207.2

0.2

1.3

3.8

0.3

192.9

0.3

192.9

0.3

8.6

2,387.5

33.7

15.4

9.4

2,122.1

9.1

36.3

9.8

107.5

35.8

8.4

0.0

PO3

208.0

0.2

1.3

3.8

2,233.8

33.7

15.4

9.4

2,122.1

9.1

2,190.4

33.7

15.4

9.4

2,122.1

192.9

0.3

8.6

1.1

2,397.9

33.7

15.4

9.4

2,122.1

36.3

9.8

107.5

19.5

35.8

8.4

77.4

38.1

39.2

5,226.3

3,155.0

641.8

1,429.5

2,543.1

9.8

35.8

8.4

0.0

32.9

5,226.3

3,155.0

641.8

1,429.5

2,985.5

3,796.8

3,155.0

641.8

1,375.2

5,226.3

3,155.0

641.8

1,429.5

2,631.6

Source: Ricardo et al. (2024), Impact assessment support study

175

The costs savings due to PM16 are limited to the time spent for preparing and printing the documents and the costs of

delivering the documents. It is assumed that around 2 minutes of work per document could be saved, at an average cost

per hour for technicians and associate professionals (ISCO level 3) of EUR 34, plus EUR 2 per document for paper and

mail cost.

kom (2025) 0180 - Ingen titel

Table 5: Recurrent and one-off costs, and costs savings for national public authorities in the policy options, in

2026, 2030 and 2050, relative to the baseline, in million EUR (2022 prices)

Difference to the baseline

PO1a

2026

Adjustment

costs

PMC2

PMC3

PMC4

PM1

PM9

PM12

PM13

PM14

PM15

Administrative

costs

PMC6

PMC7

PMC8

PMC9

PM1

PM11

PM13

PM14

PM15

PM16

PM17

Enforcement

costs

PM2

PM3

PM4

Administrative

costs savings

PMC6

PMC7

PM16

Net benefits

272.7

161.5

35.8

75.4

91.2

282.3

167.3

35.8

79.3

166.8

312.7

190.6

35.8

86.3

182.9

-2.4

78.1

86.7

197.3

161.5

35.8

203.0

167.3

35.8

226.4

190.6

35.8

272.7

161.5

35.8

75.4

35.9

282.3

167.3

35.8

79.3

149.6

312.7

190.6

35.8

86.3

164.5

14.1

0.9

0.0

1.3

0.4

0.0

1.3

0.4

0.0

1.6

1.7

2.1

1.9

2.0

272.7

161.5

35.8

75.4

31.2

2.0

2.1

282.3

167.3

35.8

79.3

145.0

2.5

2.3

312.7

190.6

35.8

86.3

159.0

14.1

0.9

0.0

1.3

0.4

0.0

1.3

0.4

0.0

0.5

0.6

176.9

18.6

8.5

1.2

133.1

0.5

115.3

0.9

0.4

0.5

111.4

0.5

129.7

0.9

0.4

0.5

125.6

0.6

161.9

18.6

8.5

1.2

133.1

113.7

0.9

0.4

0.5

111.4

128.0

0.9

0.4

0.5

125.6

197.1

18.6

8.5

1.2

133.1

0.5

14.3

0.5

5.4

122.8

0.9

0.4

0.5

111.4

0.5

1.3

0.5

5.6

138.3

0.9

0.4

0.5

125.6

0.6

1.3

0.6

6.7

14.3

0.5

5.4

1.0

14.1

0.9

3.9

1.3

0.5

5.6

1.0

1.3

0.4

4.0

1.3

0.6

6.7

1.3

0.4

4.8

4.6

0.2

0.7

2.1

0.1

1.4

33.0

0.03

9.4

0.03

9.4

0.03

33.0

0.03

3.4

9.4

0.03

0.3

9.4

0.03

0.3

33.0

0.03

3.4

0.45

197.6

18.6

8.5

1.2

133.1

9.4

0.03

0.3

0.04

123.3

0.9

0.4

0.5

111.4

9.4

0.03

0.3

0.04

139.0

0.9

0.4

0.5

125.6

0.03

0.1

0.01

0.03

0.1

0.01

2030

0.1

2050

0.1

2026

36.1

0.2

0.7

2.1

0.03

0.1

0.03

0.1

PO1b

2030

9.6

2050

9.6

2026

39.6

0.2

0.7

2.1

0.1

0.03

0.1

0.01

0.03

0.1

0.01

PO2

2030

9.9

2050

9.9

2026

39.9

0.2

0.7

2.1

0.03

0.1

0.03

0.1

PO3

2030

9.9

2050

9.9

Source: Ricardo et al. (2024), Impact assessment support study; Note: negative values for net benefits represent net costs.

Table 6: One-off costs for national public authorities in the policy options, in 2026, 2030 and 2050, relative to the

baseline, in million EUR (2022 prices)

Difference to the baseline

PO1a

2026

Adjustment

costs

PMC2

PMC3

PMC4

PM1

PM9

PM12

PM13

4.4

0.2

0.7

2.0

0.1

1.4

23.6

0.03

23.6

0.03

23.6

0.03

2030

0.0

2050

0.0

2026

26.5

0.2

0.7

2.0

PO1b

2030

0.0

2050

0.0

2026

29.7

0.2

0.7

2.0

0.1

PO2

2030

0.0

2050

0.0

2026

30.0

0.2

0.7

2.0

PO3

2030

0.0

2050

0.0

kom (2025) 0180 - Ingen titel

Difference to the baseline

PO1a

2026

PM14

PM15

Administrative

costs

PMC6

PMC7

PMC8

PMC9

PM11

PM16

PM17

Net costs

12.8

0.5

69.3

0.0

78.1

0.0

64.9

17.8

8.1

0.7

25.0

0.0

51.6

17.8

8.1

0.7

25.0

0.0

77.9

17.8

8.1

0.7

25.0

13.0

12.8

0.5

107.6

0.0

2030

2050

2026

PO1b

2030

2050

2026

3.1

PO2

2030

2050

2026

3.1

0.4

77.9

17.8

8.1

0.7

25.0

13.0

12.8

0.5

107.9

0.0

PO3

2030

2050

Source: Ricardo et al. (2024), Impact assessment support study

6.1.2. Impacts on businesses

This section describes the impacts on affected businesses, primarily PTI stations, but also garage equipment

manufacturers, garages, motor vehicle dealers, various repair workshops, vehicle manufacturers and other

businesses (i.e., vehicle owners). The costs, costs savings and other benefits by policy option are discussed

below, while the detailed calculations by policy measure are provided in Annex 4 (section 3).

6.1.2.1.

Impacts on PTI centres

The vast majority of periodic technical inspections are conducted by businesses. In some Member

States periodic technical inspections can be performed by the central licencing authority in the

country and/or public inspection centres (i.e., governmental owned vehicle inspection centres), in

addition (e.g. EL, ES, HU, LV, RO) or instead (e.g. LU) of private inspection centres. On the other

hand, in AT and NL, they are performed by thousands of commercial garages. Annex 6 provides

more details on this point. Given the diversity at Member State level and the fact that in most Member

States PTIs are mostly performed by private inspection centres (e.g., in RO, less than 5% of the tests

are performed by public authorities), the PTI centres were classified under businesses for the purpose

of this impact assessment. The precise share of periodic technical inspections carried out by private

entities is not available.

All policy options result in adjustment costs for PTI centres, while PO2 and PO3 also lead to administrative

costs. On the other hand, all policy options are expected to generate benefits for PTI centres due to the

increased number of inspections, and PO2 and PO3 will also lead to administrative costs savings (see Table

7 to Table 10).

Depending on the Member State, the additional costs for the PTI centres due to the additional

requirements per PTI may be passed through to vehicle owners (i.e. citizens and businesses). This

will depend on how PTI charges are set by the Member State: where prices are not regulated, it is

likely that PTI centres will seek to recover investment costs, possibly on a relatively short term. On

the other hand, in Member States that regulate the level of PTI charges, the evolution of those charges

will depend on the public contract agreed with the PTI service provider, potentially subject to

renegotiation, or on the price-setting policy of the authority that is itself responsible for PTI. In these

cases, costs may either be borne by the service provider/authority or be recovered over a longer

period. Considering the complexity of the process, and the uncertainty related to the degree of pass-

through of the costs as well as the time horizon for passing-through the costs, in this impact

assessment it has been assumed that the additional costs for the PTI centres are partly borne by them

kom (2025) 0180 - Ingen titel

(i.e. for those measures that would increase the cost per PTI). On the other hand, the higher costs due

to the increased number of inspections (i.e. due to the extended scope) are fully passed through to the

vehicle owners, and represent benefits for the PTI centres.

Adjustment costs.

PO1a,

adjustment costs for PTI centres are only due to common measures included

in all options, namely PMC1, PMC2, PMC3, and PMC4. They cover one-off adjustment costs (see Table

10) for: the acquisition of tools adapted to the PTI of electric and hybrid vehicles and training of inspectors

176

(PMC1), estimated at EUR 119.8 million in 2026 and EUR 24.4 million in 2030; the software update for

reading on-board diagnostics and training of inspectors

177

(PMC2), estimated at EUR 96.1 million in 2026;

the purchase of devices for the PN counting and training of inspectors

178

(PMC3), estimated at EUR 372.7

million in 2026; and, the acquisition of NOx measurement equipment and training of inspectors (PMC4)

179

estimated at EUR 1.48 billion in 2026. In addition, recurrent adjustment costs (i.e., maintenance and

calibration costs) for the PN and NOx measurement equipment are assumed at 5% of the capital costs, based

on stakeholders’ feedback, and are estimated at EUR 18.1 million per year from 2026 onwards in PMC3

and at EUR 73.3 million per year in PMC4 (see Table 9). Expressed as present value over 2026-2050, the

total one-off and recurrent adjustment costs are estimated at EUR 143.6 million for PMC1, EUR 96.1

million for PMC2, EUR 697.1 million for PMC3 and EUR 2.80 billion for PMC4 (see Table 7). Thus,

PO1a results in total one-off and recurrent adjustment costs of around

EUR 3.73 billion,

expressed as

present value over 2026-2050 relative to the baseline, of which EUR 2.09 billion one-off costs. The largest

share of total adjustment costs in PO1a is due to PMC4 (75% of the costs), followed by PMC3 (19%).

PO1b,

in addition to the costs entailed by the common measures (same as under PO1a), the mandatory

PTI for motorcycles above 125cm3 (PM2), the annual emission testing for light commercial vehicles

(PM5), the mandatory yearly testing of vehicles that are 10-year-old or older (PM6), the more advanced

testing of noise for motorcycles (PM10), and the additional emission tests for vehicles that are found as

high emitters during remote sensing or plume chasing and are sent for emission tests in a PTI centre

(PM12) will also lead to one-off and recurrent adjustment costs. For PM2, the one-off adjustment costs are

driven by the additional PTI lanes needed to deliver the inspections and the training of inspectors in the

seven Member States where PTI is currently not in place for motorcycles above 125cm3

180

and are

estimated at EUR 3.3 million in 2026 and up to EUR 40,000 per year post-2026 (see Table 10)

181

, while

the recurrent costs (i.e., maintenance costs for the PTI lanes and labour costs for the additional

inspections)

182

are estimated at EUR 8.9 million in 2030 and EUR 11.1 million in 2050 relative to the

baseline. For PM5, the one-off adjustment costs are due to the additional PN and NOx measurement

One stakeholder (FSD – the German PTI agency) provided a cost estimate of EUR 500 per tool for measuring

insulation resistance and equipotential bonding. One such tool per PTI centre would need to be acquired in 2026 by the

48,880 PTI centres in the EU, with a second one added in 2030. A three-day training per PTI inspector would be needed

for the 128,536 inspectors across EU.

177

The cost for the software update is estimated at EUR 500 per PTI tool and 128,536 PTI tools in the EU would need to

be updated. A one-day training per inspector would be needed.

178

For the 36,173 PTI centres in the EU affected by this measure (excluding BE, DE and NL, which have already

introduced such testing and are thus part of the baseline), two PN measurement devices per PTI inspection centre would

be needed. The price per PN measurement equipment is estimated at EUR 5,000. An additional half day of training related

to the use of PN-testing for 88,776 inspectors (excluding BE, DE and NL) is assumed to take place in 2026.

179

The cost per NOx measurement equipment is estimated at EUR 15,000 and each of the 48,880 PTI centres in the EU

is assumed to be equipped with two devices. An additional half day training related to the use of NOx testing is assumed

to take place for the 128,536 inspectors across EU.

180

BE, FI, IE, NL, MT, PT and DK.

181

The additional number of inspections in the 7 MS is estimated at 751,660 in 2030 and 941,911 in 2050. 204 additional

PTI lanes would be needed in total over 2026-2050 relative to the baseline. The cost per PTI lane is estimated at EUR

20,000. A two-day training for the additional inspectors is assumed.

182

Recurrent maintenance costs for the PTI lanes are assumed at 10% of the capital costs (i.e. EUR 2,000 per lane). The

labour costs per inspection are estimated at EUR 11.3.

176

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equipment needed for the annual emission testing of light commercial vehicles and training of inspectors in

all Member States, and are estimated at EUR 20.1 million. At the same time, the recurrent costs associated

with PM5 cover the maintenance costs for the equipment and the labour costs for the additional PN and

NOx testing, and they are estimated at EUR 49.2 million in 2030 and EUR 4.9 million in 2050 relative to

the baseline

183

. For PM6, 11 Member States that do not require annual PTI testing of cars and vans after 10

years of their registration would be affected

184

. The additional number of PTIs for cars due to PM6 is

estimated at 42.1 million in 2030 and 47.5 million in 2050 and for vans at 4.5 million in 2030 and 5.2 million

in 2050. Thus, this measure would require a very significant increase in the number of PTI lanes and trained

inspectors over time, with one-off adjustment costs estimated at EUR 1.01 billion in 2026, EUR 4.9 million

in 2030 and EUR 1.7 million in 2050

185

(see Table 10). It would also lead to significantly higher

maintenance costs for the PTI lanes and labour costs for performing the inspections, with total recurrent

costs estimated at EUR 886 million in 2030 and EUR 995.7 million in 2050 relative to the baseline. PM10

would result in one-off adjustment costs for the acquisition of noise measurement devices and training of

inspectors in the 23 Member States that currently do not measure L-vehicles noise emissions at PTI

186

estimated at EUR 4.7 million (see Table 10)

187

, and in recurrent costs (i.e., maintenance costs for the devices

and labour costs for the additional testing time)

188

of EUR 61.8 million in 2030 and EUR 73.7 million in

2050 relative to the baseline. For PM12, the additional number of emission tests for internal combustion

engine vehicles (i.e. for vehicles that are found as high emitters during remote sensing or plume

chasing and are sent for emission test in a PTI centre) is estimated at 2.4 million in 2030 and 174,609

in 2050 relative to the baseline

189

. PM12 is expected to lead to additional labour costs for performing

the tests, estimated at EUR 8 million in 2030 and EUR 0.6 million in 2050 relative to the baseline

190

Expressed as present value over 2026-2050, the costs of PM2 are estimated at EUR 175.7 million, those of

PM5 at EUR 647.7 million, the costs of PM6 at EUR 17.68 billion, those of PM10 at EUR 1.17 billion and

the costs of PM12 at EUR 99 million. Thus, PO1b results in total one-off and recurrent adjustment costs of

around

EUR 23.51 billion,

expressed as present value over 2026-2050 relative to the baseline, of which

EUR 3.22 billion one-off costs (see Table 7 and Table 8). The largest share of the total adjustment costs in

PO1b is by far due to PM6 (75% of the costs), followed by PMC4 (12% of the costs), PM10 (5% of the

costs) and PMC3 (3% of the costs). The common measures, together, represent only 16% of the costs.

Total one-off and recurrent adjustment costs of

PO2

are very similar to those of PO1b, without however

including the costs due to PM2. They are estimated at

EUR 23.33 billion,

expressed as present value over

2026-2050 relative to the baseline, of which EUR 3.22 billion one-off costs (see Table 7 and Table 8). The

most significant policy measures in terms of costs in PO2 are similar to those in PO1b.

PO3

includes the same adjustment costs as in PO2, but leads to additional one-off and recurrent adjustment

costs for extending the PTI to all motorcycles (PM3), for making PTI mandatory for light trailers (PM4)

183

The recurrent costs decrease over time due to the decreasing number of internal combustion light commercial vehicles

that require PN and NOx testing.

184

CY, DE, LT, CZ, DK, FR, EL, HU, IT, MT and SK.

185

Based on an interview with TUV Rheinland, the cost of a new PTI lane is assumed at EUR 50,000. Each new lane for

cars in 2026 will also require one set of PN and NOx testing equipment. Additional PN testing and NOx testing equipment

is assumed only for cars as the costs for such equipment related to vans is already reflected in PM5.

186

Few MSs (DE, ES, HR and SK) are already measuring L-vehicles noise emissions at PTI.

187

The cost for purchasing a noise measurement device is estimated at EUR 800 per device, and 2 devices are assumed

to be needed for each PTI centre with a test track. A half a day of training is assumed per inspector.

188

Recurrent adjustment costs for the maintenance and calibration of devices are assumed at 5% of the capital cost. The

additional noise testing is estimated to take around 15 minutes per PTI.

189

The decrease in the number of emission tests is driven by the increase in the number of zero-emission vehicles over

time in the baseline.

190

Due to the small share of the fleet affected it is assessed that no additional emission testing equipment will be needed

and that the available PTI lanes will be able to serve the additional demand.

kom (2025) 0180 - Ingen titel

and for further harmonisation of test methods (PM7). For PM3, the one-off adjustment costs for extending

the PTI to motorcycles from 50cm3 in the eight Member States where such requirement is currently not in

place

191

are estimated at EUR 3.8 million in 2026 and up to EUR 60,000 per year post-2026

192

, while the

recurrent adjustment costs at EUR 10.2 million in 2030 and EUR 13 million in 2050 relative to the

baseline

193

. For PM4

194

, the one-off costs for the additional PTI lanes and the training of inspectors are

estimated at EUR 1 million in 2026 and up to EUR 20,000 per year post-2026

195

, and the recurrent costs

(i.e., for the maintenance of the PTI lanes and the labour costs for the additional inspections) at EUR 11.9

million in 2030 and EUR 13.4 million in 2050. In PM7, PTI centres in the Member States with lower-

stringency roadworthiness systems will need to acquire new equipment to enhance their capacity, including

an advanced brake testing device and a suspension tester. One-off costs for equipment and training due to

PM7 are estimated at EUR 367 million in 2026 and EUR 122.2 million in 2030

196

, and recurrent costs for

maintenance at EUR 48 million in 2030 and in 2050. Thus, PO3 results in total one-off and recurrent

adjustment costs of

EUR 25.06 billion,

expressed as present value over 2026-2050 relative to the baseline,

of which EUR 3.71 billion one-off costs (see Table 7 and Table 8). The largest share of the total adjustment

costs in PO3 is by far due to PM6 (71% of the costs), followed by PMC4 (11% of the costs), and PM7 and

PM10 (5% of the costs each). The common measures, together, represent only 15% of the costs in PO3.

Garage equipment manufacturers

will benefit from the measures that require the acquisition of new

or more testing equipment by PTI centres

197

Administrative costs.

No administrative costs are expected for PTI centres under PO1a and PO1b. In

PO2

and

PO3,

administrative costs would result from the data governance (PM11), related to the need of the PTI

centres to adapt their IT systems. The one-off administrative costs for the adaptation of the IT systems is

estimated at EUR 1,000 per centre. Total one-off administrative costs would therefore amount to EUR 48.9

million in 2026 for the 48,880 PTI centres across the EU (see Table 10). In addition, recurrent administrative

costs for the maintenance of the IT systems are estimated at 10% of the capital costs, or EUR 100 per PTI

centre. Total recurrent administrative costs are thus estimated at EUR 4.9 million per year from 2026

onwards (see Table 9). Overall, PO2 and PO3 are estimated to result in total one-off and recurrent

administrative costs of

EUR 136.5 million,

expressed as present value over 2026-2050 (see Table 7).

Administrative costs savings.

The data governance (PM11), included in

PO2

and

PO3,

is also expected to

lead to administrative costs savings for the PTI centres. The access to relevant technical information would

191

192

BE, FI, IE, NL, MT, PT, DK and CY (in CY motorcycles above 125cm3 are already covered).

As in PM2, the one-off adjustment costs cover the additional PTI lanes needed to deliver the inspections and the training of

inspectors. The cost per PTI lane is the same as in PM2. This is also the case of the time required for the training of inspectors.

193

The recurrent adjustment costs, as in PM2, cover the maintenance costs for the PTI lanes and labour costs for the additional

inspections. More details are available in Annex 4 (section 3).

194

Eleven MS would be affected by PM4: 7 MS where there is currently no requirement for PTI for either O1 or O2 (DK,

EL, FI, FR, NL, IE, PT) and 4 MS where there is currently only a requirement for PTI for O2 (PL, SK, BE and ES).

195

The cost of an additional PTI lane for trailers is estimated at EUR 10,000 per lane.

196

For HDV brake testing using extrapolation methods, an average one-off cost of EUR 2,500 is assumed per PTI centre.

The purchase cost of a suspension tester for light vehicles is around EUR 10,000. Considering the 11 Member States with

lower-stringency roadworthiness systems, 29,922 of the 48,880 PTI centres would have to invest into advanced brake

testing equipment and 28,322 into suspension testers. An average of 4 hours of training is assumed per inspector.

197

Among the common measures and thus in PO1a, the most important in this respect are those related to the new

emission tests (PMC3 and PMC4). In PO1b, PO2 and PO3, these businesses would also benefit from additional demand

for testing equipment generated mainly by annual emission testing of vans (PM5), the noise testing of motorcycles

(PM10), and especially due to the annual PTI for cars and vans above 10 years of age (PM6). The benefits from mandatory

PTI for heavy motorcycles (PM2 in PO1b) would be limited since only a few Member States would be affected. PO3

would bring additional benefits to garage equipment manufacturers through testing all motorcycles and trailers (PM3 and

PM4). Furthermore, PM7 would increase the need for more advanced testing equipment.

kom (2025) 0180 - Ingen titel

bring some limited time savings for PTI centres for performing the PTIs

198

, with recurrent administrative

costs savings estimated at EUR 87.1 million in 2030 and EUR 99.3 million in 2050 (see Table 9). This is

equivalent to

EUR 1.64 billion,

expressed as present value over 2026-2050 relative to the baseline (see

Table 7). No administrative costs savings are expected for PO1a and PO1b.

Benefits from additional periodic technical inspections.

PTI centres will benefit from the extension of the

scope of PTI and more frequent testing of certain vehicle categories

199

. In

PO1a,

the benefits stemming

from the mandatory roadworthiness testing following significant modifications of the vehicle (PMC5) are

estimated at EUR 45.5 million in 2030 and EUR 52.3 million in 2050, relative to the baseline (EUR

860.5

million

expressed as present value over 2026-2050).

PO1b

includes the same benefits as PO1a, due to the

common measure (PMC5), and adds additional benefits for the PTI centres due to the mandatory PTI for

motorcycles above 125cm3 (PM2), the annual emission testing of light commercial vehicles (PM5), the

mandatory yearly testing of vehicles that are 10-year-old or older (PM6) and the additional emission tests

for vehicles that are found as high emitters during remote sensing or plume chasing and are sent for

emission tests in a PTI centre (PM12). Of these measures, the highest benefits are estimated for PM6

(1.94 billion in 2030 and EUR 2.19 billion in 2050; EUR 36.54 billion expressed as present value over

2026-2050), followed by PM5 (EUR 115 million in 2030 and EUR 9.4 million in 2050; EUR 1.46 billion

expressed as present value over 2026-2050), PM2 (EUR 15.1 million in 2030 and EUR 19 million in 2050;

EUR 294.1 million expressed as present value over 2026-2050) and PM12 (EUR 19.7 million in 2030 and

EUR 1.6 million in 2050; EUR 247.2 million expressed as present value over 2026-2050). Thus, PO1b

results in total benefits of 2.14 billion in 2030 and EUR 2.27 billion in 2050, relative to the baseline (EUR

39.39 billion

expressed as present value over 2026-2050). In

PO2

the total benefits are slightly lower than

in PO1b as it includes the same measures except for the mandatory PTI for motorcycles above 125cm3

(PM2). They are estimated in total at EUR 2.12 billion in 2030 and EUR 2.26 billion in 2050. Expressed as

present value over 2026-2050, the benefits for PTI centres due to PO2 amount to

EUR 39.10 billion.

The

highest benefits would be realised under

PO3,

which in addition to the measures of PO2, adds the extension

of PTI to all motorcycles (PM3) and the mandatory PTI for light trailers (PM4). They are estimated at EUR

2.17 billion in 2030 and EUR 2.31 billion in 2050, relative to the baseline (EUR

39.97 billion

expressed as

present value over 2026-2050). PM6 generates around 93% of the total benefits for PTI centres in PO1b

and PO2 and 91% of the total benefits in PO3.

Net costs/benefits for PTI centres.

PO1a results in net costs for the PTI centres estimated at EUR 2.87

billion, expressed as present value over 2026-2050 relative to the baseline. On the other hand, PO1b, PO2

and PO3 result in net benefits for the PTI centres, mainly driven by the measure on the yearly testing of

older vehicles. The highest net benefits are estimated for PO2 (EUR 17.27 billion, expressed as present

value over 2026-2050 relative to the baseline), followed by PO3 (EUR 16.41 billion) and PO1b (EUR 15.89

billion).

Table 7: Recurrent and one-off costs, costs savings and benefits for PTI centres in the policy options, expressed as

present value over 2026-2050 relative to the baseline, in million EUR (2022 prices)

PO1a

Adjustment costs

PMC1

PMC2

3,734.1

143.6

96.1

Difference to the baseline

PO1b

PO2

23,507.9

23,332.2

143.6

96.1

PO3

25,061.7

143.6

96.1

198

Time savings of 3 minutes are assumed per PTI. This represents 10% of the average of 30 minutes per PTI for a car.

Not all PTI centres are expected to benefit of this measure, as access to relevant information is often already available. It

is expected that only 30% of PTIs would benefit of PM11.

199

The benefits (i.e. revenues) for the PTI centres are derived based on the number of additional inspections performed

relative to the baseline, depending on the policy measure, and the PTI charges per vehicle category. More details are

provided in Annex 4 (section 3).

kom (2025) 0180 - Ingen titel

PO1a

PMC3

PMC4

PM2

PM3

PM4

PM5

PM6

PM7

PM10

PM12

Administrative costs

PM11

Administrative costs

savings

PM11

Benefits

PMC5

PM2

PM3

PM4

PM5

PM6

PM12

Net benefits

697.1

2,797.3

Difference to the baseline

PO1b

PO2

697.1

2,797.3

175.7

PO3

697.1

2,797.3

203.9

225.4

647.7

17,680.8

1,300.2

1,170.6

99.0

136.5

1,643.4

39,968.0

860.5

341.3

526.6

1,454.8

36,537.6

247.2

16,413.2

647.7

17,680.8

1,170.6

99.0

0.0

647.7

17,680.8

1,170.6

99.0

136.5

1,643.4

39,100.1

860.5

0.0

860.5

39,394.2

860.5

294.1

-2,873.6

1,454.8

36,537.6

247.2

15,886.2

1,454.8

36,537.6

247.2

17,274.7

Source: Ricardo et al. (2024), Impact assessment support study; Note: negative values for net benefits represent net costs.

Table 8: One-off costs for PTI centres in the policy options, expressed as present value over 2026-2050 relative to

the baseline, in million EUR (2022 prices)

PO1a

Adjustment costs

PMC1

PMC2

PMC3

PMC4

PM2

PM3

PM4

PM5

PM6

PM7

PM10

Administrative costs

PM11

Net costs

2,094.7

143.6

96.1

372.7

1,482.3

Difference to the baseline

PO1b

PO2

3,221.3

3,217.4

143.6

96.1

372.7

1,482.3

3.9

PO3

3,708.7

143.6

96.1

372.7

1,482.3

4.5

1.1

20.1

1,097.9

485.6

4.7

48.9

3,757.6

20.1

1,097.9

4.7

0.0

3,221.3

20.1

1,097.9

4.7

48.9

3,266.3

0.0

2,094.7

Source: Ricardo et al. (2024), Impact assessment support study

kom (2025) 0180 - Ingen titel

Table 9: Recurrent and one-off costs, costs savings and benefits for PTI centres in the policy options, in 2026, 2030

and 2050, relative to the baseline, in million EUR (2022 prices)

PO1a

2030

115.8

24.4

0.0

18.1

73.3

Difference to the baseline

PO1b

PO2

2030

2050

2026

2030

1,130

1,177

4,175

1,121

24.4

0.0

18.1

73.3

8.9

0.0

18.1

73.3

11.1

119.8

96.1

390.8

1,556

24.4

0.0

18.1

73.3

PO3

2030

1,313

24.4

0.0

18.1

73.3

10.2

11.9

49.2

886.0

170.2

61.8

8.0

4.9

87.1

2,166

45.5

17.5

28.0

115.0

1,940

19.7

934.7

Adjustment

costs

PMC1

PMC2

PMC3

PMC4

PM2

PM3

PM4

PM5

PM6

PM7

PM10

PM12

Admin costs

PM11

Admin costs

savings

PM11

Benefits

PMC5

PM2

PM3

PM4

PM5

PM6

PM12

Net benefits

2026

2,162

119.8

96.1

390.8

1,556

2050

91.4

0.0

18.1

73.3

2026

4,186

119.8

96.1

390.8

1,556

11.9

2050

1,166

0.0

18.1

73.3

2026

4,603

119.8

96.1

390.8

1,556

13.7

12.3

69.6

1,870

402.8

63.6

8.6

53.8

84.1

2,115

44.1

17.0

26.6

115.8

1,890

21.4

-2,458

2050

1,241

0.0

18.1

73.3

13.0

13.4

4.9

995.7

48.0

73.7

0.6

4.9

99.3

2,309

52.3

22.1

31.5

9.4

2,192

1.6

1,163

69.6

1,870

63.6

8.6

0.0

49.2

886.0

61.8

8.0

0.0

4.9

995.7

73.7

0.6

0.0

69.6

1,870

63.6

8.6

53.8

84.1

2,071

44.1

49.2

886.0

61.8

8.0

4.9

87.1

2,120

45.5

4.9

995.7

73.7

0.6

4.9

99.3

2,256

52.3

44.1

45.5

52.3

2,086

44.1

14.8

2,135

45.5

15.1

2,275

52.3

19.0

-2,118

-70.3

-39.1

115.8

1,890

21.4

-2,100

115.0

1,940

19.7

1,006

9.4

2,192

1.6

1,097

115.8

1,890

21.4

-2,073

115.0

1,940

19.7

1,082

9.4

2,192

1.6

1,184

Source: Ricardo et al. (2024), Impact assessment support study; Note: negative values for net benefits represent net costs.

Table 10: One-off costs for PTI centres in the policy options, in 2026, 2030 and 2050, relative to the baseline, in

million EUR (2022 prices)

Difference to the baseline

PO1a

2026

Adjustment

costs

PMC1

PMC2

PMC3

PMC4

PM2

PM3

PM4

PM5

PM6

PM7

PM10

Administrative

costs

0.0

4.7

0.0

4.7

48.9

0.0

20.1

1,012

0.0

4.9

0.0

1.7

20.1

1,012

0.0

4.9

0.0

1.7

2,071

119.8

96.1

372.7

1,482

2030

24.4

0.0

2050

0.0

2026

PO1b

2030

2050

2026

PO2

2030

2050

2026

3,479

119.8

96.1

372.7

1,482

3.8

1.0

20.1

1,012

367.0

4.7

48.9

PO3

2030

151.6

24.4

0.0

0.02

0.0

4.9

122.2

0.0

2050

1.7

0.0

0.06

0.00

0.0

1.7

0.0

3,111

119.8

96.1

372.7

1,482

3.3

29.4

24.4

0.0

0.02

1.7

0.0

0.04

3,107

119.8

96.1

372.7

1,482

29.3

24.4

0.0

1.7

0.0

kom (2025) 0180 - Ingen titel

Difference to the baseline

PO1a

2026

PM11

Net costs

2,071

24.4

0.0

2030

2050

2026

PO1b

2030

2050

2026

48.9

PO2

2030

0.0

2050

0.0

2026

48.9

3,528

PO3

2030

0.0

151.6

2050

0.0

1.7

3,111

29.4

1.7

3,156

29.3

1.7

Source: Ricardo et al. (2024), Impact assessment support study

Net costs/benefits per PTI centre.

Looking at the costs and benefits per PTI centre (see Table 11), expressed

as present value over 2026-2050, reveals that the highest total costs per PTI centre are expected in PO3

(EUR 516 thousand), followed by PO1b (EUR 481 thousand), PO2 (EUR 480 thousand) and PO1a (EUR

76 thousand). The highest benefits (including costs savings) are however also projected for PO3 (EUR 851

thousand), followed by PO2 (EUR 834 thousand), PO1b (EUR 806 thousand) and PO1a (EUR 18

thousand). The highest net benefits are however estimated for PO2 at EUR 353 thousand, followed by PO3

at EUR 336 thousand and PO1b at EUR 325 thousand, while PO1a results in net costs of around EUR 59

thousand. Net benefits in PO2 represent around 6.3% of the turnover per PTI centre, in PO3 around 6% of

the turnover, in PO1b around 5.8% of the turnover per PTI centre, while the net costs in PO1a around 1.1%

of the turnover.

Table 11: Recurrent and one-off costs, costs savings and benefits per PTI centre in the policy options, expressed

as present value over 2026-2050 relative to the baseline, in thousand EUR (2022 prices) and share of the turnover

Difference to the baseline

PO1a

Adjustment costs

Administrative costs

Administrative costs savings

Benefits from additional periodic technical inspections

Net benefits

Share of turnover (%)

Adjustment costs

Administrative costs

Administrative costs savings

Benefits from additional periodic technical inspections

Net benefits

1.4%

0.0%

0.3%

-1.1%

8.6%

0.0%

14.5%

5.8%

8.6%

0.1%

0.6%

14.4%

6.3%

9.2%

0.1%

0.6%

14.7%

6.0%

76.4

0.0

17.6

-58.8

PO1b

480.9

0.0

805.9

325.0

PO2

477.3

2.8

33.6

799.9

353.4

PO3

512.7

2.8

33.6

817.7

335.8

Source: Ricardo et al. (2024), Impact assessment support study; Note: negative values for net benefits represent net costs.

6.1.2.2.

Garages, motor vehicle dealers, tyre and repair stations, etc.

Administrative costs.

all policy options,

the requirement for Member States to set up a system to record

odometer readings from the cars and vans registered in their territory (PMC9), is expected to generate one-

off and recurrent administrative costs for vehicle repair shops (including tyre, windscreen service, etc.),

motor vehicle dealers and other garages. One-off costs for software updates, to allow them to transfer their

data to the central national database, are estimated at EUR 229 per company (in 2022 prices)

200

. These costs

are relevant for 651,351 companies (470,765 repair shops and garages and 180,586 motor vehicle

dealers)

201

, excluding those in Belgium and the Netherlands, which implemented the measure already and

are part of the baseline. Total one-off administrative costs are thus estimated at EUR 149.2 million in 2026.

In addition, recurrent administrative costs (i.e., for the maintenance of the software and the time spent for

200

European Parliament (2018), Odometer Manipulation in motor vehicles in Europe,

https://www.europarl.europa.eu/RegData/etudes/STUD/2018/615637/EPRS_STU%282018%29615637_EN.pdf

201

Eurostat, Structural business statistics, Enterprise statistics by size class and NACE Rev.2 activity.

kom (2025) 0180 - Ingen titel

recording the odometer readings) are estimated at EUR 19.4 million in 2030 and 14.9 million in 2050

relative to the baseline

202

. Thus, total one-off and recurrent administrative costs would amount to

EUR 460

million

(EUR 706 per company), expressed as present value over 2026-2050. For the purpose of the

‘one

in one out approach’,

the average annual recurrent administrative costs over 2026-2035 are estimated at

EUR 19.5 million per year

203

. Considering the 651,351 companies relevant for PMC9, the average annual

cost per company is estimated at EUR 29.9. In addition, as explained above, the one-off administrative costs

are estimated at EUR 149.2 million in 2026.

6.1.2.3.

Vehicle manufacturers

Administrative costs.

PO2

and

PO3,

automobile manufacturers will face administrative costs related to

the setting up of a governance framework for providing access to in-vehicle data necessary to carry out PTI

and RSI to inspection centres and competent authorities (PM11). According to one manufacturer, the

adjustments to their IT systems to ensure access to the relevant data are estimated at EUR 1 million. For the

20 manufacturers, the total one-off administrative costs are estimated at EUR 20 million in 2026. Recurrent

administrative costs (i.e., maintenance costs) are estimated at 10% of the capital costs or EUR 100,000 per

vehicle manufacturer. Total recurrent costs would amount to EUR 2 million per year from 2026 onwards.

Expressed as present value over 2026-2050, one-off and recurrent administrative costs are estimated at

EUR

55.9 million

relative to the baseline (EUR 2.8 million per vehicle manufacturer). No administrative costs

are expected for vehicle manufacturers in PO1a and PO1b.

6.1.2.4.

Other businesses (vehicle owners)

In all policy options, transport operators and various other businesses that own vehicles will face some

administrative costs linked to additional inspections. In all policy options they will benefit due to the

reduction in odometer fraud, while in PO1b, PO2 and PO3 they will also enjoy additional cost savings.

Administrative costs.

PO1a,

the recurrent administrative costs are linked to one common measure

(PMC5), which requires that vehicles undergo a roadworthiness test following any significant modification

that could affect safety or the environmental performance of the vehicle. The number of vehicles affected

by the measure is projected at 0.66 million in 2030 and 0.75 million in 2050 in 20 Member States

204

, and

the recurrent costs are estimated at EUR 27.8 million in 2030 and EUR 31.6 million in 2050 relative to the

baseline

205

(see Table 13). Expressed as present value over 2026-2050, total administrative costs for PO1a

amount to EUR

524.2 million

(see Table 12). Some common measures, like those related to the introduction

of mandatory PN and NOx testing (PMC3 and PMC4), may lead to a higher charge per PTI for vehicle

owners (businesses and citizens), as PTI centres may pass the additional costs of investment in equipment

for these tests to their customers. Due to the very diverse organisation of PTI in Member States

206

, including

different organisational and contractual setups between the competent authorities and PTI centres (which

may themselves be run by public authorities or agencies as well as by authorised private companies, large

or small), it is not possible to estimate the extent of such cost pass-through. Whether or not it will happen

and when will depend on the specific situation in each Member State, e.g., on the timespan of existing

202

The recurrent costs are decreasing over time due to the projected uptake of connected vehicles. No manual encoding

is needed for the connected vehicles.

203

This is calculated as a simple average over 2026-2035, non-discounted.

204

Around 0.6% of the vehicle fleet is assumed to undergo significant modifications, based on data for ES and DE. PTI

following modification is already a requirement in HR, FI, AT, NL, DE, SE and ES, and thus part of the baseline. 60%

of the cars registrations and 100% of vans, lorries and buses registrations are undertaken by businesses.

205

The charge per PTI is used to calculate the costs. For businesses, for the categories of vehicles relevant for them, the

average charge per PTI at EU level is estimated at EUR 42.1 per vehicle.

206

Cf. Annex 6, section 2 and 3.

kom (2025) 0180 - Ingen titel

agreements, service contracts, if they can be renegotiated or not, etc.

207

. On the other hand, it should be

noted that the higher costs due to the increased number of inspections (i.e. due to the extended scope)

are fully passed through to the vehicle owners and reflected in the costs calculations.

PO1b,

in addition to PMC5, the annual emission testing for light commercial vehicles (PM5), the yearly

testing of vehicles that are 10-year-old or older (PM6), the additional emission tests for vehicles that are

found as high emitters during remote sensing or plume chasing and are sent for emission tests in a PTI centre

(PM12), and the regular inspection of cargo securing (PM13) will lead to recurrent administrative costs for

businesses. For PM5, affecting all Member States, the additional number of emission testing for internal

combustion light commercial vehicles is estimated at 14.2 million in 2030 and 1.2 million in 2050 relative

to the baseline

208

, and the recurrent costs at EUR 115 million in 2030 and EUR 9.4 million in 2050 (EUR

1.46 billion expressed as present value over 2026-2050). For PM6, eleven Member States only require an

inspection every two years for cars and vans after 10 years of their registration

209

. Thus, the measure is

expected to result in a doubling of the number of inspections for vehicles over 10 years old in these Member

States, with costs for businesses (vehicles owners) estimated at EUR 1.24 billion in 2030 and EUR 1.40

billion in 2050 (EUR 23.3 billion expressed as present value over 2026-2050). For PM12, business that own

cars, vans and heavy duty vehicles will incur extra costs for emissions testing if the vehicles are identified

as high emitters via the use of remote sensing or plume chasing and are sent for PTI due to the 0.5% limit

in the capacity for roadside inspections. The recurrent administrative costs are estimated at EUR 14 million

in 2030 and EUR 1.2 million in 2050 (EUR 175 million expressed as present value over 2026-2050)

210

. For

PM13

211

, the extra costs for the additional time for cooperating on the cargo securing inspections would

amount to EUR 0.44 million in 2030 and EUR 0.55 million in 2050

212

(EUR 8.5 million expressed as

present value over 2026-2050). Thus, total administrative costs for PO1b are estimated at

EUR 25.46

billion,

expressed as present value over 2026-2050. Costs related to PM6 would represent 92% of the total

costs of PO1b.

PO2

includes the same costs as in PO1b, and additional recurrent administrative costs related to the

extension of the scope of application of roadside inspections to light commercial vehicles (PM14). The extra

costs for the additional time for cooperating on roadside inspections in PM14

213

would amount to EUR 10.9

million in 2030 and EUR 12.9 million in 2050

214

(EUR 208 million, expressed as present value over 2026-

2050). Total recurrent administrative costs for PO2 are therefore estimated at

EUR 25.67 billion,

expressed

as present value over 2026-2050 relative to the baseline. The largest share of the costs in PO2 would be due

to PM6 (91% of the costs).

PO3

includes the same costs as in PO2, and in addition it reflects costs related to the mandatory PTI for

light trailers (PM4). Businesses (vehicle owners) would be affected by PM4 when introduced in eleven

207

For example, in Ireland, the changes introduced by the 2014 RWP have not resulted in any increase in PTI charges. Any price

increase would require government decision based on a detailed business case. However, the PTI operator can still claim indexation

through the reduction of a levy that it pays to the competent authority after each test, while keeping the charge per PTI unchanged.

208

The decrease in the number of emission testing is driven by the decrease in the number of internal combustion light

commercial vehicles over time. This is due to the Regulation on CO

standards for LDVs that is included in the baseline.

209

CY, DE, LT, CZ, DK, FR, EL, HU, IT, MT and SK.

210

The cost of an emission test is estimated at 20% of the PTI charge per vehicle. Around 60% of cars and 100% of vans

and heavy duty vehicles are owned by businesses.

211

Owners of heavy-duty vehicles would be affected by the measure to be introduced by 5 MS (EE, FR, IE, LV and LU).

212

They are calculated considering an average hourly labour cost of EUR 21.9 for drivers (ISCO 8 - Plant and machine

operators and assemblers), the average time per inspection of 20 minutes, and the additional number of roadside

inspections (44,813 in 2030 and 55,526 in 2050).

213

22 MS will be affected by the measure (except ES, HU, SE, SK and FI, that already conduct such inspections).

214

They are calculated considering an average hourly labour cost of EUR 21.9 for drivers (ISCO 8 - Plant and machine

operators and assemblers), the average time per inspection of 20 minutes, and the additional number of roadside

inspections (497,627 in 2030 and 588,721 in 2050).

kom (2025) 0180 - Ingen titel

Member States

215

, with recurrent administrative costs estimated at EUR 20.4 million in 2030 and EUR 23.1

million in 2050 (EUR 385.1 million, expressed as present value over the 2026-2050 period). Total recurrent

administrative costs for PO3 are thus estimated at

EUR 26.05 billion,

expressed as present value over 2026-

2050. Costs related to PM6 represent 89% of the total costs of PO3 and PM5 6% of the costs.

Administrative costs savings.

Administrative costs savings are expected to arise in

PO1b, PO2 and PO3

from the possibility to avoid emission testing at PTI in case the vehicle passed a roadside inspection or was

found to be in line with the applicable emission limits during a screening by remote sensing (PM12). The

number of PTI tests avoided by businesses due to PM12 is estimated at 11.9 million in 2030 and EUR 1

million in 2050

216

. The savings (see Table 12 and Table 13) would amount to EUR 102.6 million in 2030

and EUR 10.1 million in 2050 (EUR

1.29 billion

expressed as present value over 2026-2050).

Benefits due to avoided odometer fraud.

In all policy options, the requirement for mandatory recording and

reporting to a national central database of vehicle mileage, whenever a vehicle undergoes repair/

maintenance or in the case of tyre changes/replacement (PMC9)

217

offers very significant benefits to

businesses in relation to the reduction of odometer fraud, which currently affects around 4.8% of vehicles

in national second-hand sales and 11.3% in cross-border sales. The benefits to businesses due to the avoided

odometer fraud reduction are estimated at EUR 6.35 billion in 2030 and EUR 6.99 billion in 2050

218

Expressed as present value over 2026-2050 the benefits amount to EUR 118.34 billion, relative to the

baseline. It should however be acknowledged that there is uncertainty regarding the economic damage

caused by odometer fraud and the number of cars affected. For this reason, sensitivity analysis has been

performed and is reported in section 7.5 and Annex 4 (section 7).

Net benefits/costs for businesses (vehicle owners).

All policy options are expected to result in significant

net benefits for businesses (vehicle owners), mainly due to the avoided odometer fraud. The highest net

benefits are estimated for PO1a (EUR 117.82 billion), followed by PO1b (EUR 94.17 billion), PO2 (EUR

93.96 billion) and PO3 (EUR 93.58 billion) (see Table 12).

Table 12: Recurrent costs, costs savings and benefits for other businesses (vehicle owners) in the policy options,

expressed as present value over 2026-2050 relative to the baseline, in million EUR (2022 prices)

PO1a

524.2

Difference to the baseline

PO1b

PO2

25,458.4

524.2

1,454.8

23,295.9

175.0

8.5

0.0

1,287.3

25,666.4

524.2

1,454.8

23,295.9

175.0

8.5

208.0

1,287.3

PO3

26,051.5

524.2

385.1

1,454.8

23,295.9

175.0

8.5

208.0

1,287.3

Administrative costs

PMC5

PM4

PM5

PM6

PM12

PM13

PM14

Administrative costs

savings

PM12

215

7 Member States where there is currently no requirement for PTI for either O1 or O2 (DK, EL, FI, FR, NL, IE, PT)

and 4 Member States where there is currently only a requirement for PTI for O2 (PL, SK, BE and ES).

216

The reason for the decreasing number of PTI tests avoided over time is the increasing share of zero-emission vehicles

in the baseline scenario.

217

PMC9 is relevant for all Member States, except Belgium and the Netherlands that have already introduced such requirement.

218

The average cost of mileage fraud, due to higher purchase price and maintenance costs incurred, is estimated at EUR

2,119 per vehicle in 2022 prices drawing on a Belgian Car-Pass study (https://www.car-

pass.be/files/article_files/file/7/crm%2520study%2520final%2520report.pdf).

More explanations are provided in section

2 of Annex 4.

kom (2025) 0180 - Ingen titel

PO1a

Benefits

PMC9

Net benefits

118,340.5

117,816.3

Difference to the baseline

PO1b

PO2

118,340.5

94,169.4

118,340.5

93,961.3

PO3

118,340.5

93,576.3

Source: Ricardo et al. (2024), Impact assessment support study

Table 13: Recurrent costs, costs savings and benefits for other businesses (vehicle owners) in the policy options, in

2026, 2030 and 2050, relative to the baseline, in million EUR (2022 prices)

Difference to the baseline

PO1a

2026

Administrative

costs

PMC5

PM4

PM5

PM6

PM12

PM13

PM14

Administrative

costs savings

PM12

Benefits

PMC9

Net benefits

0.0

109.4

6,043

6,016

6,353

6,325

6,991

6,959

6,043

4,791

102.6

6,353

5,062

10.1

6,991

5,558

115.8

1,204

14.8

0.4

115.0

1,237

14.0

0.4

9.4

1,400

1.2

0.5

115.8

1,204

14.8

0.4

10.5

109.4

6,043

4,780

115.0

1,237

14.0

0.4

10.9

102.6

6,353

5,051

9.4

1,400

1.2

0.5

12.9

10.1

6,991

5,545

27.0

2030

27.8

2050

31.6

2026

1,362

27.0

PO1b

2030

1,394

27.8

2050

1,443

31.6

2026

1,372

27.0

PO2

2030

1,405

27.8

2050

1,456

31.6

2026

1,392

27.0

19.3

115.8

1,204

14.8

0.4

10.5

109.4

6,043

4,761

PO3

2030

1,425

27.8

20.4

115.0

1,237

14.0

0.4

10.9

102.6

6,353

5,030

2050

1,479

31.6

23.1

9.4

1,400

1.2

0.5

12.9

10.1

6,991

5,522

Source: Ricardo et al. (2024), Impact assessment support study

6.1.3. Impacts on citizens (vehicle owners)

Vehicle owners can be businesses or citizens. This section discusses only impacts on citizens

219

. The

impacts on businesses as vehicle owners are discussed in section 6.1.2.4. In all policy options citizens are

expected to be faced with administrative costs, but also with adjustment costs savings and benefits due to

avoided odometer fraud. In addition, PO1b, PO2 and PO3 would result in administrative costs savings (see

Table 14 and Table 15).

Administrative costs for citizens.

PO1a,

the recurrent administrative costs for citizens are linked to one

common measure which extends the PTI to cover vehicles with significant modifications (PMC5), and to

the introduction of roadside inspections for motorcycles over 125cm3 as an alternative to PTI (PM1). For

PMC5, the number of vehicles affected is estimated at 0.45 million in 2030 and 0.53 million in 2050 in 20

Member States

220

, and the recurrent administrative costs (based on the number of vehicles affected and the

cost per PTI) at EUR 17.7 million in 2030 and EUR 20.6 million in 2050 (EUR 336.3 million, expressed

as present value over 2026-2050). For PM1, the extra costs for the time spent for cooperating on roadside

inspections with the public authorities are estimated at EUR 0.4 million in 2030 and EUR 0.5 million in

219

Around 40% of cars are owned by citizens (see e.g.,

https://www.transportenvironment.org/challenges/cars/company-

cars/

and

https://cleantechnica.com/2022/12/08/european-company-car-market-goes-green/).

For motorcycles, it is

assumed that 100% are owned by citizens, in lack of more detailed information.

220

Around 0.6% of the vehicle fleet is assumed to undergo significant modifications, based on data for ES and DE. PTI

following modification is already a requirement in HR, FI, AT, NL, DE, SE and ES, and thus part of the baseline.

kom (2025) 0180 - Ingen titel

2050

221

(EUR 7.9 million, expressed as present value over 2026-2050). Total administrative costs in PO1a

are thus estimated at

EUR 344.2 million,

expressed as present value over 2026-2050. As explained in

section 6.1.2.4, some common measures, like those related to the introduction of mandatory PN and NOx

testing (PMC3 and PMC4), may lead to a higher charge per PTI for vehicle owners (businesses and

citizens), as PTI centres may pass the additional costs of investment in equipment for these tests to their

customers. However, as explained in section 6.1.2.4, it is not possible to estimate the extent of such cost

pass-through. On the other hand, it should be noted that the higher costs due to the increased number of

inspections (i.e. due to the extended scope) are fully passed through to the vehicle owners and reflected in

the costs calculations.

In the case of

PO1b,

in addition to the costs of the common measure (PMC5), there will be some additional

administrative costs for the owners of motorcycles in a few Member States

222

as a result of the mandatory

PTI for motorcycles above 125cm3 (PM2), as well as additional costs due to the mandatory yearly testing

of vehicles older than 10 years (PM6) and due to the additional emission tests for vehicles that are found as

high emitters during remote sensing and are sent for emission tests in a PTI centre (PM12). The related

administrative costs for citizens due to PM2 are estimated at EUR 15.1 million in 2030 and EUR 19 million

in 2050 (EUR 294.1 million, expressed as present value over 2026-2050). PM6 generates administrative

costs estimated at EUR 703.4 million in 2030 and EUR 792.3 million in 2050

223

(EUR 13.24 billion

expressed as present value over 2026-2050). For PM12, citizens that own cars will incur extra costs for

emissions testing if the vehicles are identified as high emitters via the use of remote sensing and are sent for

PTI due to the 0.5% limit in the capacity for roadside inspections. The recurrent administrative costs are

estimated at EUR 5.8 million in 2030 and EUR 0.3 million in 2050 (EUR 72.2 million expressed as present

value over 2026-2050)

224

. Thus, total administrative costs for citizens under PO1b for the period 2026-2050

are estimated at

EUR 13.94 billion

relative to the baseline.

PO2,

the recurrent administrative costs for citizens are driven by the costs of the common measure

(PMC5), the introduction of roadside inspections for motorcycles over 125cm3 as an alternative to PTI

(PM1), the mandatory yearly testing of vehicles older than 10 years (PM6) and the additional emission tests

for vehicles that are found as high emitters during remote sensing and are sent for emission tests in a PTI

centre (PM12). The total administrative costs for citizens under PO2 for the period 2026-2050 are estimated

EUR 13.66 billion

relative to the baseline.

The highest impact on administrative costs for citizens is expected in

PO3,

where additional costs relative

to PO2 are due to mandatory extension of PTI to all motorcycles (PM3), mandatory PTI for light trailers

(PM4), and the extension of the scope of application of roadside inspections to 2- and 3-wheeled vehicles

(PM15). PM6 generates by far the highest administrative costs in PO3, estimated at EUR 703.4 million in

2030 and EUR 792.3 million in 2050 (EUR 13.24 billion expressed as present value over 2026-2050). For

PM3, the recurrent administrative costs are estimated at EUR 17.5 million in 2030 and EUR 22.1 million

in 2050

225

(EUR 341.3 million over the period 2026-2050), while in PM4 at EUR 7.6 million in 2030 and

EUR 8.4 million in 2050 (EUR 141.5 million, expressed as present value over 2026-2050). Finally, the

extension of the scope of application of roadside inspections to 2- and 3-wheeled vehicles is expected to

221

The additional number of roadside inspections is estimated at 82,566 in 2030 and 104,321 in 2050 in the MS affected

(BE, FI, IE, NL, MT and PT). The average time required for a roadside inspection is estimated at 10 minutes and the

average hourly labour cost at EUR 29.5.

222

BE, FI, IE, NL, MT, PT and DK.

223

11 MS (CY, DE, LT, CZ, DK, FR, EL, HU, IT, MT and SK) only require an inspection every two years for cars and

vans after 10 years of their registration. Thus, the measure is expected to result in a doubling of the number of inspections

for vehicles over 10 years old in these Member States. More details are provided in Annex 4 (section 3).

224

The cost of an emission test is estimated at 20% of the PTI charge per vehicle.

225

The additional number of inspections in the 8 MS affected (BE, FI, IE, NL, MT, PT, DK, CY) is estimated at 869,017

in 2030 and 1,097,479 in 2050. In Cyprus motorcycles above 125cm3 are already covered.

kom (2025) 0180 - Ingen titel

result in some costs due to the time spent for cooperating on inspections, estimated at EUR 0.9 million in

2030 and EUR 1.1 million in 2050 (EUR 16.9 million for the period 2026-2050). The total administrative

costs for citizens due to PO3 would amount to

EUR 14.15 billion,

expressed as present value over 2026-

2050 relative to the baseline (see Table 14).

Other costs for citizens.

The measures aimed at increasing the effectiveness of the PTI and RSI, along with

new testing requirements regarding safety, air pollutant emissions and noise, will lead to an increased

number of vehicle owners experiencing repair costs to ensure that their vehicles can pass the PTI inspection

and remain in use. This may mean costs to replace breaks, axles, suspensions systems, lamps, or other

defective components, such as a defective emission control system. It is difficult to estimate these costs as

this may vary significantly in each case and for each vehicle type. Such costs are also expected to be higher

as vehicles get older. Due to the number of uncertainties, it was not possible to develop an estimate of such

costs. It should however be noted that these costs are not considered regulatory costs linked to this initiative.

Adjustment costs savings for citizens.

Adjustment cost savings for citizens are expected to come from the

measures related to the recognition of PTI certificates in other Member States, as a result of avoided travel

costs back to the country of vehicle registration for a PTI. The highest costs savings are expected in

PO3,

which includes the obligation for PTI certificate issued in any Member State to be recognised by the

Member State of registration (PM7). They are estimated at EUR 228.2 million in 2030 and EUR 254.8

million in 2050, relative to the baseline. Expressed as present value over 2026-2050, the cost savings for

PO3 amount to

EUR 4.29 billion

relative to the baseline. In

PO1b

and

PO2

the cost savings are driven by

the recognition of the PTI certificate issued by a Member State other than Member State of registration of

up to six months (PM8) and are estimated at EUR 114.1 million in 2030 and EUR 127.4 million in 2050.

Expressed as present value over 2026-2050, they are estimated at

EUR 2.14 billion

relative to the baseline.

PO1a

shows the lowest costs savings for citizens (vehicle owners) among the options, linked to the

recognition of PTI certificates on the basis of bilateral agreements (PM9). The savings are estimated at EUR

49 million in 2030 and in 2050 (EUR

878.2 million

relative to the baseline, expressed as present value over

2026-2050).

Administrative costs savings for citizens.

Under

PO1b, PO2

and

PO3,

citizens will benefit from

administrative cost savings related to the option for Member States not to require emission testing at PTI

after the vehicle has successfully passed a screening by remote sensing (PM12), i.e., it has been found to

emit below the emission limits applicable to it. The corresponding savings amount to EUR 48.8 million in

2030 and are expected to drop to around EUR 2.8 million by 2050 (EUR

591.9 million

expressed as present

value over the 2026-2050 period). No administrative costs savings are expected in PO1a.

Benefits due to avoided odometer fraud.

all policy options,

the obligation for Member States to record

odometer readings in a national database, as well as to make them available to other Member States in the

case of a re-registration of a vehicle (PMC9), is expected to help reduce odometer fraud in the Member

States where such a system is not currently in place

226

(i.e., both in domestic sales of used vehicles and in

cross-border sales, where odometer tampering has been found to be more common). The corresponding

benefits for citizens are estimated at EUR 3.55 billion in 2030 and EUR 3.86 billion in 2050. Expressed as

present value over 2026-2050, they are estimated at around

EUR 65.67 billion

relative to the baseline. As

explained in section 6.1.2.4, it should be acknowledged that there is uncertainty regarding the economic

damage caused by odometer fraud and the number of cars affected. For this reason, sensitivity analysis has

been performed and is reported in section 7.5 and Annex 4 (section 7).

Net benefits for citizens.

All policy options are expected to result in net benefits for citizens (vehicle

owners). Expressed as present value over 2026-2050 relative to the baseline (see Table 14), they are

226

Only BE and NL have introduced such requirement.

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estimated to be the highest in PO1a (EUR 66.20 billion), followed by PO3 (EUR 56.40 billion), PO2 (EUR

54.75 billion) and PO1b (EUR 54.46 million).

Table 14: Recurrent costs, costs savings and benefits for citizens (vehicle owners) in the policy options, expressed

as present value over 2026-2050 relative to the baseline, in million EUR (2022 prices)

PO1a

344.2

336.3

7.9

Difference to the baseline

PO1b

PO2

13,944.3

13,658.1

336.3

294.1

341.3

141.5

13,241.7

72.2

16.9

4,289.3

336.3

7.9

PO3

14,150.0

336.3

Adjustment costs

PMC5

PM1

PM2

PM3

PM4

PM6

PM12

PM15

Adjustment costs savings

PM7

PM8

PM9

Administrative costs savings

PM12

Benefits

PMC9

Net benefits

13,241.7

72.2

878.2

2,144.6

878.2

0.0

65,666.9

66,200.9

591.9

65,666.9

54,459.0

13,241.7

72.2

2,144.6

591.9

65,666.9

54,745.2

591.9

65,666.9

56,398.0

Source: Ricardo et al. (2024), Impact assessment support study

Table 15: Recurrent costs, costs savings and benefits for citizens (vehicle owners) in the policy options, in 2026,

2030 and 2050, relative to the baseline, in million EUR (2022 prices)

Difference to the baseline

PO1a

2026

Administrative

costs

PMC5

PM1

PM2

PM3

PM4

PM6

PM12

PM15

Adjustment

costs savings

PM7

PM8

PM9

Administrative

costs savings

PM12

Benefits

PMC9

Net benefits

49.0

0.0

49.0

0.0

49.0

0.0

53.4

3,381

3,412

3,554

3,585

3,857

3,885

3,381

2,820

48.8

3,554

2,975

2.8

3,857

3,155

53.4

3,381

2,834

48.8

3,554

2,990

2.8

3,857

3,173

53.4

3,381

2,920

48.8

3,554

3,078

2.8

3,857

3,269

49.0

110.7

114.1

127.4

110.7

114.1

127.4

686.5

6.5

703.4

5.8

792.3

0.3

686.5

6.5

703.4

5.8

792.3

0.3

17.5

17.1

0.4

2030

18.1

17.7

0.4

2050

21.1

20.6

0.5

14.8

15.1

19.0

17.0

7.3

686.5

6.5

0.8

221.5

110.7

114.1

127.4

110.7

114.1

127.4

17.5

7.6

703.4

5.8

0.9

228.2

22.1

8.4

792.3

0.3

1.1

254.8

2026

724.9

17.1

PO1b

2030

742.0

17.7

2050

832.3

20.6

2026

710.6

17.1

0.4

PO2

2030

727.3

17.7

0.4

2050

813.8

20.6

0.5

2026

735.3

17.1

PO3

2030

752.8

17.7

2050

844.9

20.6

Source: Ricardo et al. (2024), Impact assessment support study

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6.1.4. Impacts on competitiveness

The stakeholders that participated in the survey were requested to assess the impact of each measure on the

cost and price competitiveness of sectors affected, with a score of 1 representing a very negative impact and

a score of 7 representing a very positive impact. According to the consulted stakeholders, a somewhat

positive impact on the cost and price competitiveness of affected sectors would be expected from the

introduction of new PTI/RSI test requirements (average 3.89). A similarly positive impact on the cost and

price competitiveness of sectors affected is expected by the stakeholders that participated in the survey from

measures widening the scope of vehicles to be tested, and increased frequency of testing for certain vehicle

categories. Finally, recognising PTIs conducted in Member States other than the Member State of

registration would be expected by the stakeholders to achieve almost no impact (average 3.12).

As explained in section 6.1.2.1, the biggest share of the additional adjustment costs for

PTI centres

compared to the baseline is related to measures requiring the upgrade of equipment and facilities (PMC3

and PMC4), included in all policy options, the annual emission testing for light commercial vehicles (PM5),

the mandatory yearly testing of vehicles that are 10-year-old or older (PM6) and the requirement for more

advanced emission and noise testing (PM10) in PO1b, PO2 and PO3, and the required investment in new

equipment, including an advanced brake testing device and a suspension tester (PM7) under PO3. To a

lesser extent, the extension of the scope of the vehicles covered (PM3 and PM4) also leads to additional

adjustment costs under PO3. All policy options, and in particular PO1b, PO2 and PO3 will also result in

greater revenue sources for testing centres, thanks to more vehicles having to undergo PTI. Overall, as

explained in section 6.1.2.1, PO2 results in net benefits of EUR 353 thousand per PTI centre expressed as

present value over 2026-2050 relative to the baseline, followed by PO3 with EUR 336 thousand and PO1b

with net benefits of EUR 325 thousand per PTI centre, while PO1a results in net costs of around EUR 59

thousand per PTI centre. Net benefits in PO2 represent around 6.3% of the turnover per PTI centre, in PO3

around 6% of the turnover, in PO1b around 5.8% of the turnover per PTI centre, while the net costs in PO1a

around 1.1% of the turnover. Even though the analysis shows that PO1a may result in net direct costs for

PTI centres, these costs may be passed through to vehicle owners (citizens and businesses) through higher

PTI charges or compensated by the competent public authorities (see discussion on cost pass-through under

administrative costs for other businesses - section 6.1.2.4, and for citizens - section 6.1.3). It can thus be

concluded that PO1a is not expected to have a significant negative impact, while PO1b, PO2 and PO3 are

expected to have very positive impact on the competitiveness of PTI operators.

Garages and other repair workshops

will be affected by the requirement to record odometer readings of

every vehicle they service (PMC9). As described in section 6.1.2.2, total one-off and recurrent

administrative costs would amount to EUR 706 per company, expressed as present value over 2026-2050,

which is not expected to have any significant impact on their competitiveness. Some of them, as well as

vehicle manufacturers and dealers already record odometer readings for the purpose of keeping a

maintenance schedule.

Other businesses (vehicle owners)

may face somewhat higher costs as a result of the additional PTI costs

and more frequent roadside inspections in all policy options (in particular in PO1b, PO2 and PO3), but the

estimated extra costs in the case of HGVs are limited; they are more significant for passenger cars. At the

same time, a more effective enforcement of the roadworthiness framework will ensure fair competition,

reducing the opportunities for gaining price advantage on the basis of lower vehicle standards, and

avoidance of the required maintenance costs of vehicles.

6.1.5. Impacts on innovation and technological development

Positive impacts on innovation are expected from requiring more stringent and advanced test methods that

also need to be adjusted to the general requirement for a PTI to be quick, simple and affordable. Although

kom (2025) 0180 - Ingen titel

new tests, such as PN- and NOx-measurement, ePTI or advanced brake and noise tests are based on existing

technologies, there is still a certain degree of development and adaptation necessary to ensure their

widespread application. The consulted stakeholders expect a positive impact on the innovative capacity of

the sectors affected from measures related to new PTI/RSI test requirements, improved access and exchange

of information and the digitalisation of vehicle documents. Furthermore, increased demand for new test

methods and equipment can be expected to generate further development of relevant technologies by

developers of measurement equipment, a viewpoint supported by the representatives of the sector in their

contribution to the stakeholder consultation. Together with that, relevant training of inspectors to the new

test methods will enhance the availability of technical skills and expertise that can have a broader positive

impact. As such, most of the common measures are expected to have some positive impact on innovation

(PMC1 on the testing of electric vehicles, PMC2 using ePTI, PMC3 and PMC4 on new emission tests,

PMC6 on digital PTI certificates, and PMC7 on more efficient exchange of vehicle data).

While in the case of PO1a the digitalisation of the registration certificates (PM16) may require further

innovation, PO1b would introduce remote sensing and plume chasing (PM12) to monitor air pollutants and

noise emitted by vehicles. Remote sensing also relies on existing technologies but requires adaptations to

scale them up to cover the desired share of the vehicle fleet. Deploying these technologies at a larger scale

than today would also necessitate process innovation. PO2 and PO3 combine the benefits of both measures.

6.1.6. Impacts on small and medium enterprises (SMEs)

Periodic technical inspections are in many Member States performed by smaller independent garages.

Moreover, roadside inspections under the RSI Directive have been specifically targeted at commercial

vehicle fleets, which are predominantly operated by SMEs. Garages, motor vehicle dealers, tyre and repair

workshops, etc., almost entirely SMEs, will be affected by the requirement for Member States to set up a

system to record odometer readings from the cars and vans registered in their territory. Therefore, the

initiative is considered relevant for SMEs, and the SME test has been performed. More detailed explanations

on the impacts on SMEs and SME test (including the four SME steps) are provided in Annex 10.

As explained in section 2.2.3, various forms of tampering affect the safety and environmental performance

of vehicles. Next to odometer fraud, tampering may relate to disconnecting or altering the emission and

noise reduction systems or modifying the performance of the vehicle. As regards possible impacts on the

SME tuning sector, this initiative is not intended to cover legitimate tuning that is authorised and

documented/registered by the competent authorities. It only refers to illegal activity where modifications

are not authorised and documented/registered by the competent authorities. The possible impacts on the

SME tuning sector have thus not been considered.

6.1.7. Impact on the functioning of the internal market and competition

The existing divergence between vehicle registration documents and the information included and quality

of the data stored in the vehicle registers creates challenges in coordinating enforcement actions by Member

States. Furthermore, the non-recognition of roadworthiness certificates among EU Member State creates

additional trade barriers for cross-border operation or sale of vehicles, hindering the efficient functioning of

the internal market, business operations and the freedom of movement of people within the EU. All policy

options are expected to have a positive impact on the functioning of the internal market.

The combination of the measures related to improving the availability and exchange of vehicle-related

information, making the roadworthiness certificate available in electronic format, the specific measure on

odometer fraud, harmonising testing methods, the frequency of testing, requirements for the improvement

of the PTI and the scope of testing, can have a positive impact on the functioning of the internal market and

on competition. Qualitative assessment shows that PO2 and especially PO3 are expected to have the highest

positive impact on the internal market and competition. PO2 incorporates additional measures aimed at

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extending roadside inspections to light commercial vehicles, and facilitating access to vehicle data necessary

for thorough testing by PTI centres. This comprehensive approach is expected to have a stronger impact

than PO1a and PO1b due. PO3 has a stronger positive impact due to PM7, which requires that a PTI

certificate issued in any Member State is recognised by the Member State of registration, as well as further

harmonisation of test methods. In addition, PO3 introduces mandatory PTI for all motorcycles and light

trailers, which are not currently tested by all Member States. The inclusion of L-category vehicles in the

scope of RSI (PM15) is expected to reduce the number of tampered vehicles. PO3 applies more ambitious

measures regarding the standardisation of tests methods than provisions already included in the other policy

options. As such, PO3 is expected to deliver the most significant positive impact on the internal market and

competition. A more detailed discussion is presented in Annex 13.

6.1.8. Territorial impacts

There is no inherent bias (positive or negative) of the proposed options towards specific regions or territories

of the European Union, and no specific differences among the different policy options. The underlying

measures are expected to be applied in a more harmonised way in terms of the test procedures to be followed

in comparison to the baseline scenario. There may be a limited number of specific issues that arise for

authorities and vehicles owners in different regions of the European Union. These may relate to the

implications of different climatic conditions when performing relevant tests (e.g., warm engine NOx test in

Nordic countries) or the long distances needed to reach a PTI centre, and the extra costs that would arise for

citizens and businesses in less dense and/or remote regions from widening the scope of vehicles subject to

PTI and/or increasing the frequency of testing. Furthermore, there are different profiles of level of

ownership, frequency of use, and size of motorcycles across the EU (e.g., motorcycles in most Southern

European countries are smaller and are used more often for daily commute, in comparison to Northern

European countries where motorcycles are more often used for leisure). In that respect, PO3 (including an

extended scope to motorcycles of more than 50cc) could have a greater impact. However, PTI for smaller

size motorcycles is already mandatory in some Southern European countries including in Italy, Spain, and

Greece. It would be left open to Member States – in the implementation of the specific measures – to adapt

the testing procedures to reflect the specific climatic conditions or to support the operation of mobile PTI

units to minimise the time and cost for citizens in remote areas.

6.1.9. Digital by default

All policy options will have a positive impact on the application of the ‘digital by default’ principle. The

mandatory electronic format of roadworthiness certificates (PMC6) should have a positive impact on

administrative costs for authorities and contribute to digital transformation in the EU. PMC7 will, for the

process of re-registration, save time and costs for authorities and citizens by moving away from information

and data exchange via e-mail etc. which is less efficient in accessing relevant vehicle data. The impact would

be even higher in PO1a, PO2 and PO3 relative to PO1b, as those options also include the issuing of vehicle

registration certificates in electronic format (PM16), combined with an extension of the information to be

included in the certificates (PM17). A digital registration certificate should help reduce time and costs by

making access and exchange of the relevant information easier, faster. The introduction of digital

registration certificates will be a further step towards the alignment of the RWP legal framework with

Regulation (EU) 2018/1724 on the Single Digital Gateway, which requires that Member States ensure that

vehicle registration procedures are delivered in a fully digital way when a citizen moves from one Member

State to another. In all cases the expectation is that while roadworthiness and registration certificates will be

issued in electronic format, there will still be a possibility for vehicle owners to obtain (or print) the relevant

documents with the introduction of a QR code. This should help to minimise accessibility issues arising for

specific parts of the population.

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6.1.10. Reporting obligations

In should be noted that the current reporting requirements under the three Directives is minimal. Therefore,

there is no scope for further reducing the reporting requirements.

6.2.

Social impacts

6.2.1. Impacts on road safety

Given that the general objective of the initiative is to improve road safety in the EU, several measures to

achieve this objective were included in the policy options. Direct impact on road safety is expected due to

the more effective identification of vehicles with major and dangerous defects in the fleet, which should

lead to the reduction of road crashes caused by technical defects and, as a result, to reduced fatalities and

injuries (serious and light). Policy options also include other measures contributing to road safety, which

relate to better implementation and enforcement of the roadworthiness legislation (such as the exchange of

data among Member States’ authorities).

Several assumptions were used to establish the impacts on road safety. They are explained in detail, by

policy measure, in Annex 4 (section 4.1). These inputs

227

were subsequently used in the PRIMES-

TREMOVE model to derive the impacts on the number of lives saved and injuries avoided. The impacts

on road safety assessed are only linked to the measures considered in this impact assessment. More detailed

explanations on the impacts by policy option and policy measure are provided in Annex 4 (section 5.1).

It should be noted that an important element in this assessment relates to the contribution of vehicle technical

defects to road crashes

228

. For this assessment, a conservative approach was taken assuming a 4%

contribution of technical defects to road crashes in the case of light-duty vehicles, heavy-duty vehicles and

trailers and 6% in the case of motorcycles. Considering the uncertainty, a sensitivity analysis has been

performed and is included in section 7.5 and Annex 4 (section 7).

All policy options are expected to result in lives saved and injuries avoided relative to the baseline scenario.

Table 16 provides the reduction in the number of fatalities and injuries relative to the baseline in 2030 and

2050, as well as the cumulative number of lives saved, and injuries avoided relative to the baseline over the

2026-2050 horizon. Cumulatively, over the period 2026-2050, PO3 is expected to result in 7,013 lives

saved, followed by PO2 (6,912 lives saved), PO1b (6,847 lives saved) and PO1a (4,661 lives saved). The

numbers of severe and slight injuries avoided follow a similar pattern with PO3 having the highest impact,

followed by PO2, PO1b, and PO1a. More explanations on the impacts by policy option and policy measure

are provided in Annex 4 (section 5.1).

Table 16: Expected reduction in the number of fatalities and injuries in the POs relative to the baseline, in 2030

and 2050, and cumulative reduction over the period 2026-2050

Fatalities

Serious injuries

Slight injuries

PO1a

2030

195

1,768

9,929

2050

173

1,587

9,011

Cumulative over 2026-2050

4,661

42,272

239,803

% reduction

1.1%

1.2%

1.3%

PO1b

2030

287

2,711

15,099

2050

253

2,420

13,658

Cumulative over 2026-2050

6,847

64,640

364,155

227

228

See more details in Annex 4 (section 4.1) on the inputs by measure and their aggregation into policy options.

As explained in section 2.1.1, various studies indicate that their share as a contributing factor of the cause of crashes

is between 3 and 19%, depending on the scope and methodology of the study; for motorcycles, it is 5% to 12% of crashes.

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Fatalities

% reduction

1.6%

PO2

2030

289

2050

255

Cumulative over 2026-2050

6,912

% reduction

1.6%

PO3

2030

293

2050

259

Cumulative over 2026-2050

7,013

% reduction

1.6%

Source: Ricardo et al. (2024), Impact assessment support study

Serious injuries

1.8%

2,721

2,429

64,885

1.8%

2,753

2,460

65,686

1.8%

Slight injuries

1.9%

15,162

13,712

365,665

1.9%

15,274

13,826

368,498

2.0%

Table 17 provides the reduction in the external costs of accidents relative to the baseline, expressed as

present value over the 2026-2050 period. The 2019 Handbook on the external costs of transport

229

was used

to monetise the costs

230

. As a result of the positive impacts on lives saved and injuries avoided presented

above, PO3 shows the highest impact in terms of reduction in the external costs of accidents relative to the

baseline (expressed as present value over the 2026-2050 period), estimated at EUR 75.2 billion. It is

followed by PO2 with EUR 74.2 billion, PO1b with EUR 73.9 billion, and PO1a with EUR 48.1 billion.

Table 17: Reduction in the external costs of accidents in the POs relative to the baseline, expressed as present

value over the 2026-2050 horizon, in 2022 prices (million EUR)

PO1a

PO1b

PO2

PO3

Fatalities

11,677

17,498

17,633

17,902

Serious injuries

21,348

33,235

33,299

33,821

Slight injuries

15,053

23,196

23,251

23,521

Total

48,079

73,929

74,183

75,244

Source: Ricardo et al. (2024), Impact assessment support study

6.2.2. Impact on employment

Measures involving an extension of vehicle scope or increase in testing frequency for particular vehicle

categories will lead to additional inspections and the need for additional inspectors to perform them. The

impact on the number of full-time RSI and PTI inspectors employed, relative to the baseline, has been

estimated on the basis of the additional number of inspections required in each policy option

231

. The impacts

on the number of full-time RSI and PTI inspectors in 2026, 2030, and 2050, relative to the baseline, are

provided in Table 18 and Table 19, respectively. It should be noted that RSI inspectors are employed by

and generate costs for national public authorities (discussed in section 6.1.1), while PTI inspectors by PTI

centres (included under businesses and discussed in section 6.1.2.1).

Apart from the indirect positive impact on garage equipment manufacturers, related to the need for new

testing equipment (in particular under PMC3 and PMC4), no direct impacts on employment are expected

from the common set of measures.

PO1a

is expected to increase the number of full-time

RSI inspectors

16 in 2030 and 20 in 2050 relative to the baseline. The impact on employment for PO1a is solely driven by

PM1, which requires additional RSI inspectors to perform inspections of motorcycles over 125cc for those

229

230

https://op.europa.eu/en/publication-detail/-/publication/9781f65f-8448-11ea-bf12-01aa75ed71a1

Based on the Handbook, the external cost of a fatality in 2022 prices is estimated at around EUR 3.5 million, that of

a serious injury at around EUR 0.5 million and that of a slight injury at around EUR 0.04 million. These values are

multiplied by the number of fatalities, serious and slight injuries, respectively, to monetise the external costs of accidents

in the context of this impact assessment.

231

The number of inspections per inspector is dependent on the assumed time taken to perform the required procedure and the

location of the test (either at PTI centres or at the roadside).

kom (2025) 0180 - Ingen titel

Member States where there is no PTI currently in place. No direct impact on employment for PTI centres

is expected under this policy option.

PO1b

is expected to increase the number of full-time

PTI inspectors

by 18,923 in 2030 and 20,322 in 2050,

relative to the baseline. The increase in employment is mainly a result of PM2 and PM5 (PTI for

motorcycles and annual emission testing for vans), PM6 (the mandatory yearly testing of vehicles that are

10-year-old or older), PM10 (noise testing of motorcycles at PTI) and PM12 (for the additional emission

tests for vehicles that are found as high emitters during remote sensing or plume chasing and are sent

for emission test in a PTI centre). Of these, PM6 is expected to have by far the largest impact as it involves

more frequent testing of around a quarter of the EU car and van fleet. No direct impact on employment for

RSI inspectors

is expected under this policy option.

For

PO2

the increase in the number of full-time

PTI inspectors

is slightly lower than in PO1b (18,752 in

2030 and 20,107 in 2050, relative to the baseline). This is driven by the annual emission testing of vans

(PM5), the mandatory yearly testing of vehicles that are 10-year-old or older (PM6), by the noise testing of

motorcycles at PTI (PM10) and by the additional emission tests for vehicles that are found as high

emitters during remote sensing or plume chasing and are sent for emission test in a PTI centre

(PM12). Unlike PO1b, PO2 does not include the effect of PM2. PO2 is also expected to increase the number

of full-time

RSI inspectors

by 204 in 2030 and 243 in 2050, relative to the baseline. The impact of PO2 on

the number of full-time

RSI inspectors

is mostly due to PM14, which requires to extend roadside inspections

to 2% of the fleet of vans. PM1 also requires additional inspectors relative to the baseline, to inspect

motorcycles over 125cc for those Member States where there is no PTI currently in place.

PO3

measures are expected to lead to 19,047 additional full-time

PTI inspectors

in 2030 and 20,357 in

2050, relative to the baseline. Similarly to PO2, PO3 includes the impacts of PM5, PM6, PM10 and PM12.

In addition, PM3 and PM4 also require additional inspectors from 2026 in PO3. PO3 is also expected to

lead to an increase in the full-time

RSI inspectors

of 248 in 2030 and 283 in 2050, relative to the baseline.

The increase in RSI employment for PO3, relative to the baseline, is due to the extension of the RSI scope

to cover vans (PM14) and L-category vehicles (PM15).

Table 18: Increase in the number of full-time RSI inspectors by policy option, relative to the baseline, in 2026,

2030 and 2050

Difference to the baseline

PO1a

PO1b

PO2

PO3

2026

197

242

2030

204

248

2050

243

283

Source: Ricardo et al. (2023), Impact assessment support study

Table 19: Increase in the number of full-time PTI inspectors by policy option, relative to the baseline, in 2026,

2030 and 2050

Difference to the baseline

PO1a

PO1b

PO2

PO3

2026

18,448

18,281

18,569

2030

18,923

18,752

19,047

2050

20,322

20,107

20,357

Source: Ricardo et al. (2023), Impact assessment support study

As well as the increase in the number of inspectors employed, there will be benefits from the additional

training for the inspectors that will be needed to be able to deliver the new testing methods. The impact on

inspectors’ skills will be positive for all policy options, with PO3 offering the greatest impact. Furthermore,

the need for additional testing equipment for new test procedures and additional inspections will lead to

kom (2025) 0180 - Ingen titel

indirect employment benefits for the wider equipment supply chain and distribution network. In particular,

the demand for additional and new testing equipment will lead to an increase in production-related jobs

within Member States (provided that manufacturing capabilities are available within the EU27). Also, there

will be employment benefits related to providing ongoing maintenance for the new testing equipment. In

particular, measures concerning new emission testing equipment (PMC3 and PMC4) could increase

equipment-related employment.

6.2.3. Impacts on fundamental rights

The policy options were assessed to determine if they have an impact on the fundamental rights and/or equal

treatment of EU citizens. The starting point of the assessment of the fundamental rights is the Charter of

Fundamental Rights of the European Union

232

. All POs were assessed having regard to the relevant EU

instrument and it was concluded that they maintain full respect for human and fundamental rights, and none

will have any negative impact thereon. A more detailed analysis is provided in Annex 12.

6.3.

Environmental impacts

The analysis of environmental impacts covers the air pollutant emissions, CO

emissions, noise emissions

and natural resources. One of the general objectives is contributing to sustainable mobility, therefore the

environmental benefits are an important justification for the initiative. In the first step, the expected

contribution of each measure on the identification and removal of high emitter vehicles (whether due to

defective emissions control systems or tampering) from the fleet is defined. It is assumed that high emitters

identified will undergo repair (whether this refers to the replacement of malfunctioning filters, sensor or

noise reduction system or the necessary modifications of the engine). The reduction of high emitters by

policy option relative to the baseline is then used as input in the PRIMES-TREMOVE model to calculate

the reduction in air pollutant emissions, and in the external costs of air pollution emissions and noise

233

. The

impacts on environmental outcomes assessed are only linked to the measures considered in this impact

assessment. More detailed explanations of the inputs used by policy measure are included in section 4.2 of

Annex 4. A detailed discussion of the impacts on air pollution and noise emissions by policy option is

provided in section 5.2 of Annex 4. A qualitative assessment is provided for the impacts on CO

emissions

and natural resources.

Impacts on air pollutant emissions.

The analysis of the impact on emissions has focused on the two

pollutants that are targeted in the proposed measures, NOx and particulate matter (particulates). Other

pollutants have not been considered although it is possible that by targeting high emitters for these two

pollutants, there will also be benefits related to other air pollutants (e.g. CO, HC, SO2). Table presents the

expected impact on the level of emissions in comparison to the baseline for each policy option. PO2 and

PO3 are expected to have the highest cumulative impact on air pollutants reduction over 2026-2050 (3,969

kilo-tonnes of NOx in PO2 and 3,970 kilo-tonnes of NOx in PO3, and 199 kilo-tonnes of PM in both PO2

and PO3), representing a decrease of 21% and 18.7% for NOx and PM, respectively, relative to the baseline.

PO1b shows somewhat lower levels of emissions reductions (20.8% for NOx and 18.5% for PM). PO1a is

expected to bring the least reduction of both air pollutants over the 2026-2050 period (3,176 kilo-tonnes of

NOx, representing a 16.8% reduction relative to the baseline, and 135 kilo-tonnes of PM, representing

12.7% reduction).

232

https://commission.europa.eu/aid-development-cooperation-fundamental-rights/your-rights-eu/eu-charter-

fundamental-rights_en

233

The 2019 Handbook on the external costs of transport (Source:

https://op.europa.eu/en/publication-detail/-

/publication/9781f65f-8448-11ea-bf12-01aa75ed71a1)

has been used to monetise the costs.

kom (2025) 0180 - Ingen titel

Table 20: Impact on air pollutant emissions (kilo tonnes of NOx and PM2.5 avoided relative to the baseline in 2030

and in 2050, and cumulative over 2026-2050; % change in cumulative air pollution emissions relative to the

baseline)

2030

2050

Cumulative

% change to

over 2026-2050

baseline

NOx (kilo tonnes of NOx avoided)

PO1a

200.5

12.1

3,176

-16.8%

PO1b

253.1

13.9

3,925

-20.8%

PO2

255.9

14.0

3,969

-21.0%

PO3

255.9

14.0

3,970

-21.0%

PM2.5 (kilo tonnes of PM avoided)

PO1a

7.8

0.6

135

-12.7%

PO1b

12.0

0.8

196

-18.5%

PO2

12.1

0.8

199

-18.7%

PO3

12.1

0.8

199

-18.7%

Source: Ricardo et al. (2024), Impact assessment support study

The external cost savings due to the reduction of air pollutant emissions (NOx and PM) were calculated

using the 2019 Handbook on the external costs of transport

234

. PO2 and PO3 are expected to lead to the

highest levels of reduction in external costs, estimated at around EUR 76.1 billion, expressed as present

value over the 2026-2050 period. This is slightly higher than in PO1b (EUR 75.2 billion) and much higher

than in PO1a (EUR 58.7 billion). Results are presented in Table .

Table 21: Reduction in the external costs of air pollutant emissions relative to the baseline, expressed as present

value over 2026-2050, in 2022 prices (million EUR)

PO1a

PO1b

PO2

PO3

Reduction in external costs related to NOx emissions

46,966

58,054

58,646

58,659

Reduction in external costs related to PM emissions

Total reduction in external costs of air pollutant emissions

Source: Ricardo et al. (2024), Impact assessment support study

11,707

58,673

17,193

75,247

17,429

76,075

17,429

76,088

Impact on noise emissions.

The impact on the reduction of high emitters and thereby on noise is expected

to be the lowest in PO1a as it does not contain any measure directly targeted at noise (it has a small positive

impact through 6, the assumed introduction of roadside checks for motorcycles in six Member States where

they are not fully covered by PTI

235

). A higher impact is expected in the case of PO1b and PO2, combining

more advanced noise testing in PTI (PM10) and use of remote sensing to support roadside inspections

(PM12). For PO2 and PO3, additional positive impacts can also arise from the increase in roadside

inspection of vans but the highest impacts in terms of noise reduction are expected in PO3, due to the

mandatory RSI for motorcycles (PM15). Table 22 presents the estimated reduction in the external costs of

noise for the four policy options, with PO3 providing the largest savings of around EUR 7.8 billion,

expressed as present value over 2026-2050 relative to the baseline. PO1b and PO2 are expected to bring

similar reductions in the external costs of noise (EUR 7.3 billion over the same period). The reduction under

PO1a would be significantly lower (EUR 0.2 billion). As for the costs of accidents and air pollution, the

external costs of noise were calculated using the PRIMES-TREMOVE model, based on the 2019 Handbook

on the external costs of transport.

234

235

https://op.europa.eu/en/publication-detail/-/publication/9781f65f-8448-11ea-bf12-01aa75ed71a1

BE, FI, IE, MT, NL, PL.

kom (2025) 0180 - Ingen titel

Table 22: Reduction in the external costs of noise emissions relative to the baseline, expressed as present value

over 2026-2050, in 2022 prices (million EUR)

PO1a

PO1b

PO2

PO3

Reduction in external costs related to noise emissions

154

7,323

7,319

7,757

Source: Ricardo et al. (2024), Impact assessment support study

Impact on CO

emissions and climate change.

emissions are not tested as part of the roadworthiness

and roadside inspections and the measures included in this analysis are not expected to have a direct impact

on the CO

emissions of vehicles. Any impact on CO

emissions may only be indirect in case there would

be reductions in the fuel consumption as a result of PTI inspections. Measure PM5 that introduces more

frequent emission testing for vans from year 1, and PM6 on the annual testing of vehicles older than 10

years could potentially have such an impact, but it is expected to remain very limited and has not been

quantified. The reduction in particulate matter (soot) is not only expected to improve air quality but probably

also have a positive impact on climate change. Since dark particles absorb sunlight, warm the atmosphere

and cause faster melting of snow and ice, they have a warming effect on the climate

236

. However, the extent

of the net impact taking various indirect effects (including in cloud formation) into account is still uncertain

and subject to ongoing research

237

. Although such an impact on climate change has not been quantified,

recent calculations indicate that it may be substantial

238

Impact on natural resources.

Some of the measures under consideration are expected to have a direct

impact on the use of natural resources. These include the requirement for the PTI certificate to be issued in

electronic format only (PMC6, included in all policy options), and issuing the registration certificates in

electronic format (PM16, included in PO1a, PO2 and PO3). Both can be expected to bring saving in terms

of the use of paper that will be proportionate to the number of PTIs and vehicle registrations. However, their

impact may be lower in the short term due to continued provision of paper versions on request. The

replacement of paper PTI certificates with digital copies is projected to affect 161.5 million vehicles in 2026,

167.3 million vehicles in 2030 and 190.6 million in 2050. The replacement of paper registration certificates

with digital copies is projected to affect 24.1 million new vehicles in 2026, 25.3 million new vehicles in

2030 and 27.6 million in 2050. Hence the savings from electronic PTI certificates are expected to be much

greater than for electronic registration certificates.

Regarding the impact on biodiversity, it is considered that the reduction of NOx emissions from road

transport may also have positive impact on the health of ecosystems, due to their reduced indirect exposure

related to chronic accumulation of nitrogen. This impact, while established in various studies and

reviews

239

, was however not analysed and quantified for this initiative since it is expected to be indirect and

limited.

All policy options are consistent with the environmental objectives of the

European Green Deal

(though

contributing to these objectives at varying degrees as outlined above) and the

European Climate Law

240

All policy options contribute towards Sustainable Development Goals SDG 3.

No significant harm

expected on the environment in any of the policy options.

236

237

See e.g.https://climate.nasa.gov/explore/ask-nasa-climate/3271/aerosols-small-particles-with-big-climate-effects/

See also Bond, T. C., et al. (2013), Bounding the role of black carbon in the climate system: A scientific assessment,

J. Geophys. Res. Atmos., 118, 5380–5552, doi:10.1002/jgrd.50171.

238

Mayer, A.C., Mayer, J., Wyser, M. et al. Particulate Filters for Combustion Engines to Mitigate Global Warming.

Estimating the Effects of a Highly Efficient but Underutilized Tool. Emiss. Control Sci. Technol. (2024).

https://doi.org/10.1007/s40825-023-00236-x

239

Ricardo-AEA Ltd for Natural (2016), Such as the ecological effects of air pollution from road transport: an updated

review.

240

Regulation (EU) 2021/1119

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OW DO THE OPTIONS COMPARE

7.1.

Effectiveness

The assessment of effectiveness looks at the extent to which the policy options meet the general and specific

objectives (SO) of the intervention. Table provides the link between policy objectives and assessment

criteria.

Table 23: Link between objectives and assessment criteria

Objectives

General objectives

GO1- Improve road safety in the EU

GO2 – Contribute to sustainable mobility

GO3 - Facilitate the free movement of persons and

goods in the Union

% reduction in the level of fatalities and injuries and associated

external costs

% reduction in the level of air pollutant emissions and noise

from road transport and associated external costs

Removal of obstacles to re-registration of vehicles in another

MS related to roadworthiness legal framework

Removal of obstacles related to the roadworthiness testing of

vehicles (recognition of certificates issued by other MSs)

Use of available test methods and procedures to assess the

roadworthiness of vehicles, including new internal combustion

engine and electric vehicles, and their electronic safety and

emission control systems

Impact (% of reduction) on the number of defective vehicles

Impact (% reduction) on the number of vehicles with tampered

emission/noise control system

Impact (% reduction) on the number of vehicles with tampered

odometer

SO3 - Improve electronic storage and exchange of

relevant vehicle identification and status data

Reduction of time/costs associated with the access to relevant

vehicle data by inspection centres and enforcement and

registration authorities.

Assessment criteria

Specific objectives

SO1 – Ensure the adequacy, consistency,

objectivity and quality of roadworthiness testing of

today's and tomorrow's vehicles

SO2 – Significantly reduce fraud and tampering,

and improve the detection of defective vehicles

All policy options contribute to the

general objective

increasing road safety in the EU

through more

effective identification of vehicles with major and dangerous defect in the fleet. The most effective policy

options are PO3 (7,013 lives saved and 65,686 serious injuries avoided), PO2 (6,912 lives saved and 64,885

serious injuries avoided) and PO1b (6,847 lives saved and 64,640 serious injuries avoided), while for PO1a

a smaller positive effect is expected (4,661 lives saved and 42,272 serious injuries avoided). All policy

options will also

contribute to sustainable mobility

by reducing air pollutant and noise emissions. This

will lead to a reduction of external costs of these emissions, with the most effective options being PO3

(external costs savings from the reduction of air pollutants and noise estimated at EUR 83.8 billion), PO2

(external costs savings estimated at EUR 83.4 billion) and PO1b (external costs savings estimated at EUR

82.6 billion). PO1a, as the least effective, is expected to bring external costs savings of EUR 58.8 billion.

All policy options will

facilitate the free movement of persons and goods in the EU

through removal of

obstacles to re-registration of vehicles in another Member State, where PO1a, PO2 and PO3 are expected

to be similarly effective, while PO1b is expected to be less effective due to the absence of measures on

digital vehicle registration certificate and additional data included in the vehicle register. Regarding

removing obstacles related to the roadworthiness testing of vehicles, PO3 is expected to be the most

effective option due to EU wide recognition of PTI certificates in another Member State extended to all

vehicles, followed by PO2 and PO1b (limited EU wide recognition of PTI certificates) and PO1a as the

least effective (bilateral agreements on recognition of PTI certificates).

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Thanks to the common set of measures, all policy options are effective in reaching

the specific objectives.

The differences in their overall effectiveness are linked to their focus, and thus the inclusion of additional

measures aimed at further addressing one or the other specific objective.

As regards

SO1,

all options can be expected to bring significant benefits through introducing test methods

for the inspection of electric vehicles, improved emission testing for internal combustion engine vehicles

(NOx and PN measurement), and the introduction of testing ADAS and other safety systems required by

the General Safety Regulation. PO1b, PO2 and PO3 are expected to perform better than PO1a as they would

bring additional positive impacts through the introduction of mandatory cargo securing inspections and new

ways of testing, such as plume chasing and remote sensing to monitor pollutant and noise emissions. PO2

and PO3 go even further than PO1b with the data governance measures to define the procedures and means

of access to vehicle technical information by PTI centres, that should also contribute to the enhanced quality

and consistency of inspections.

In terms of the achievement of

SO2,

all options are expected to lead to a reduction of defective and tampered

vehicles through improved detection, thanks to the new ways of testing, as well as to systematically

addressing odometer fraud. PO1b, PO2 and PO3 are however expected to be significantly more effective,

due to the increase in the scope of vehicles covered (mandatory yearly testing of vehicles over 10 years old).

PO1b and PO3 are more effective than PO2 in reducing the negative externalities associated with

motorcycles (mandatory PTI versus optional in the other two options).

Roadside inspections are an effective complementary measure when it comes to the identification of

tampering of emission and noise control systems, the latter especially for motorcycles, that are much more

difficult to capture as part of the PTI since they are very easy to manipulate. Therefore, PO2 and PO3 are

expected to be more effective, given that both extend RSI to light commercial vehicles, and in the case of

PO3, also to motorcycles. Nevertheless, the differences between PO3 and PO1b and PO2 in terms of the

expected level of reduction of defective vehicles and high emitters are relatively small, essentially linked to

the more comprehensive approach of PO3, i.e. the inclusion of all motorcycles in both PTI and RSI. PO3 is

expected to be the most effective in addressing SO2, closely followed by PO2and PO1b, while PO1a is

expected to be significantly less effective.

In relation to

SO3,

all options can be expected to make a positive contribution based on the common

measures on the mandatory electronic roadworthiness certificate, access to relevant PTI and registration

data for national authorities by using a common interface and the harmonisation and regular update of

technical data in vehicle registration documents. PO1a, PO2 and PO3 are expected to bring additional

benefits due to the extension of data included in the vehicle register database and the introduction of the

vehicle registration document in digital format. Moreover, PO2 and PO3 are expected to be more effective

than PO1a and PO1b because of improved data governance and enhanced access to relevant vehicle

technical information for PTI centres. Taken together, while there are limited differences among the four

policy options in meeting the SO3, PO2 and PO3 appear to be most effective, followed by PO1a, and PO1b

being the least effective option.

Overall, option PO3 seems to be the most effective when considering the expected contribution towards the

achievement of all general and specific objectives, closely followed by PO2. PO1a is the least effective –

especially in relation to specific objectives SO1 and SO2. PO1b is almost as effective as PO2 in terms of

SO1 and SO2, but is expected to be less effective in the case of objective SO3. A more detailed assessment

of the effectiveness, including quantified impacts per objective can be found in Annex 9.

7.2.

Efficiency

Efficiency concerns the ‘extent to which objectives can be achieved for a given cost (cost effectiveness)’.

The estimates of costs and benefits are summarised in Table .

kom (2025) 0180 - Ingen titel

Table 24: Summary of costs and benefits of policy options – present value over 2026-2050 compared to the baseline

(in million EUR), in 2022 prices

PO1a

PTI centres

Adjustment costs

Administrative costs

Administrative costs savings

Benefits

Garages, motor vehicle dealers,

tyre and repair stations, etc.

Administrative costs

OEMs

Administrative costs

Other businesses - vehicle owners

Administrative costs

Administrative costs savings

Benefits

Citizens

Administrative costs

Adjustment costs savings

Administrative costs savings

Benefits

National public authorities

Adjustment costs

Administrative costs

Enforcement costs

Administrative costs savings

External costs savings

Air pollution

Accidents

Noise

Total costs

Total benefits

Net benefits

Benefits to costs ratio

3,734.1

0.0

860.5

Difference to the baseline

PO1b

PO2

23,507.9

0.0

39,394.2

23,332.2

136.5

1,643.4

39,100.1

PO3

25,061.7

136.5

1,643.4

39,968.0

460.0

0.0

524.2

0.0

118,340.5

344.2

878.2

0.0

65,666.9

7.0

2,233.8

0.0

5,226.3

58,673.1

48,078.8

154.2

7,303.3

297,878.5

290,575.2

40.8

460.0

0.0

25,458.4

1,287.3

118,340.5

13,944.3

2,144.6

591.9

65,666.9

198.3

2,190.4

32.9

3,796.8

75,246.6

73,929.4

7,323.4

65,792.3

387,721.5

321,929.2

5.9

460.0

55.9

25,666.4

1,287.3

118,340.5

13,658.1

2,144.6

591.9

65,666.9

207.2

2,387.5

0.0

5,226.3

76,074.5

74,183.0

7,319.4

65,903.9

391,577.8

325,674.0

5.9

460.0

55.9

26,051.5

1,287.3

118,340.5

14,150.0

4,289.3

591.9

65,666.9

208.0

2,397.9

77.4

5,226.3

76,087.7

75,244.2

7,756.7

68,598.9

396,102.1

327,503.2

5.8

Source: Ricardo et al. (2023), Impact assessment support study

Total costs

are projected to be the lowest in PO1a, estimated at EUR 7.3 billion expressed as present value

over 2026-2050 relative to the baseline, followed by PO1b (EUR 65.8 billion), PO2 (EUR 65.9 billion) and

PO3 (EUR 68.6 billion). Of these, adjustment costs for PTI centres (for equipment, training, and additional

inspectors to perform the inspections) represent around 51% of the total costs in PO1a, 36% in PO1b, 35%

of the total costs in PO2 and 37% in PO3. Administrative costs for other businesses (i.e., vehicle owners),

for additional periodic technical inspections and cooperating on roadside inspections with the public

authorities, represent another important element of the total costs (7% of total costs in PO1a, 39% in PO1b

and in PO2 and 38% in PO3). This is also the case of administrative costs for citizens (for additional periodic

technical inspections and cooperating on roadside inspections with the public authorities), estimated at 5%

of the total costs in PO1a and 21% of total costs in PO1b, PO2 and PO3. The large share of administrative

costs for other businesses and citizens (i.e., vehicle owners) in PO1b, PO2 and PO3 is related to the

mandatory yearly testing for vehicles that are 10-year-old or older (PM6). Finally, administrative costs for

national public administrations are expected to represent around 31% of the total costs in PO1a and below

4% in PO1b, PO2 and PO3. In PO1a these relate to the setup of the database with odometer readings and

kom (2025) 0180 - Ingen titel

the operation of the system (PMC9). Other costs represent a relatively small share of the total costs in all

policy options.

Total benefits

are estimated at EUR 297.9 billion in PO1a, EUR 387.7 billion in PO1b, EUR 391.6 billion

in PO2 and EUR 396.1 billion in PO3, expressed as present value over 2026-2050 relative to the baseline.

Of these, external costs savings related to air pollutant emissions, noise emissions and accidents would

represent around 36% in PO1a and 40% in PO1b, in PO2 and in PO3. Benefits for citizens and other

businesses (i.e., vehicle owners) due to the avoided odometer fraud would represent 62% of the total benefits

in PO1a, 47% in PO1b and in PO2 and 46% in PO3. In addition, the mandatory yearly testing for vehicles

that are 10-year-old or older (PM6) would lead to additional benefits for the PTI centres in PO1b, PO2 and

PO3 due to the higher number of inspections relative to the baseline. The total benefits for the PTI centres

are estimated at around 10% of the total benefits in PO1b, PO2 and PO3. Other costs savings represent a

relatively small share of the total benefits in all policy options.

Overall, all policy options result in

net benefits

relative to the baseline. PO3 shows the highest net benefits,

estimated at EUR 327.5 billion expressed as present value over 2026-2050, followed by PO2 (EUR 325.7

billion), PO1b (EUR 321.9 billion) and PO1a (EUR 290.6 billion). PO1a shows the highest benefits to costs

ratio among the options (40.8), followed by PO1b (5.9), PO2 (5.9) and PO3 (5.8).

Among the measures included in the policy options, it should be noted that the setup of the database with

odometer readings and the operation of the system (PMC9, included in all options) is estimated to lead to

the highest benefits to costs ratio (69.8). The mandatory yearly testing for older vehicles (PM6, included in

PO1b, PO2 and PO3) is estimated to lead to benefits to costs ratio of 1.4, the mandatory PTI for light trailers

(PM4, included in PO3) to benefits to costs ratio of 0.7, and the policy measures focusing on motorcycles

to benefits to costs ratios of 2.4 to 20.2. More specifically, for motorcycles the policy measures focusing on

roadside inspections (PM1, included in PO1a and PO2; and PM15, included in PO3) show much higher

benefits to costs ratio (20.2 for PM1 and 18.5 for PM15) than measures extending the PTI (PM2, included

in PO1b with benefits to costs ratio of 2.4; and PM3, included in PO3, with benefits to costs ratio of 2.5).

This is because of the higher effectiveness of the roadside inspections relative to PTI. More details on the

calculation of the benefits to costs ratios for these measures are provided in Annex 4 (section 6).

7.3.

Coherence

Internal coherence

assesses how various elements of the proposed options are expected to work together

to achieve the objectives. Although all four policy options address the identified specific objectives and

underlying problem drivers, they do so in different ways, and with a different level of intervention. All

policy options ensure internal coherence. Among the four options, PO2 and PO3 are expected to benefit

from a broader range of synergies that can contribute to a higher level of achievement of the objectives.

This is thanks to their more comprehensive approach compared to PO1a and PO1b. Synergies indicated

in relation to PO1a and PO1b are expected to increase in the case of PO2 and PO3, containing more

comprehensive sets of measures and even lead to extra synergies, for example due to measures on

registration certificates and more harmonised registered data. The differences between PO2 and PO3

are limited. They consist in PO3 proposing almost complete harmonisation in the area of roadworthiness

testing: in terms of testing methods, full recognition of PTI certificates, and the full coverage of smaller

motorcycles (down to 50 cm

) and light trailers by PTI, as well as RSI for motorcycles. On the other hand,

PO2 addresses the bulk of the issues/inconsistencies.

External coherence

focuses on the compliance of the initiative with other EU instruments and relevant EU

policies, as well as national policies or international obligations. All identified policy options show strong

links to several EU instruments. In terms of external coherence, all policy options are considered consistent

with relevant EU strategies and legal instruments and contribute to EU policy priorities. PO1b (focussing

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on more and better testing), as well as PO2 and PO3 perform best when it comes to coherence with the road

safety policies, notably the “Vision Zero” objective. The same is true as regards coherence with the EU’s

green policies, such as the European Green Deal, the Sustainable and Smart Mobility Strategy, the Zero

Pollution Action Plan and the air quality legislation. On the other hand, PO1a, PO2 and PO3 are more

coherent with digital policies (e.g. the Single Digital Gateway, Data Act) than PO1b. In relative terms, PO3

and PO2 are expected to be the most coherent with the policy objectives in related EU legislation and

strategies, followed by PO1b and PO1a being slightly less coherent. In relation to the well-established

national policies in the field, however, stronger interventions, in particular in PO3, are less coherent. This is

further explained under section 7.4 below. Detailed comparison of policy options regarding internal and

external coherence is provided in Annex 14.

7.4.

Subsidiarity and proportionality

Regarding subsidiarity, and as described in sections 3.2 and 3.3, EU action is justified on the basis that

Member States alone would not be able to reach the objectives of the initiative, i.e., updating the harmonised

rules on roadworthiness testing, including coordinated exchange of vehicle-related data. What differentiates

the policy options beyond the common measures necessary to achieve the objectives at a minimum level is

their focus (between PO1a and PO1b) and the extent to which they can fulfil the objectives (PO2 and PO3

going beyond the other two). In terms of proportionality, as the level of intervention and associated costs

increase from PO1a to PO3, the level of positive impacts also increases, although not proportionally (as

shown by the efficiency ratios).

In general, the scope of the options is limited to what can best be achieved at the EU level (in terms of

harmonisation of methods and scope of testing, as well as in finding common solutions to ensure efficient

sharing and access to the necessary vehicle data). All policy options comply with the principle of

subsidiarity and proportionality, with PO3 possibly going somewhat beyond what is necessary to

reach the objectives. This may be the case in particular with requiring full recognition of PTI

certificates, which may not be compatible with existing structural differences in the way Member

States have set up their periodic testing involving, among others, significant differences in pricing,

granting concessions and differences in the structural organisation of the PTIs. In addition, it could

be argued that the need to introduce PTI for light motorcycles and trailers, which primarily circulate

on national territory, may be best assessed by Member States. More detailed analysis on subsidiarity

and proportionality is provided in Annex14.

Table 25 provides a summary of the comparison of the options against the baseline scenario in terms of

effectiveness, efficiency, coherence, subsidiarity, and proportionality. The following ranking symbols have

been used: from '+' (more effective/efficient/coherent/proportionate than the baseline) to '+++' (much more

effective/efficient/coherent/proportionate than the baseline).

Table 25: Comparison of options in terms of effectiveness, efficiency, coherence, subsidiarity and proportionality

relative to the baseline

Impacts

Effectiveness

Road safety (GO1)

Reduced fatalities by

Reduced severe injuries by

Reduced slight injuries by

External cost savings (billion EUR)

Air pollution and noise (GO2)

Reduction of NOx emissions (kt)

PO1a

4,661

42,272

239,803

48.1

(++)

3,176

PO1b

6,847

64,640

364,155

73.9

(+++)

3,925

PO2

++/+++

6,912

64,885

365,665

74.2

(+++)

3,969

PO3

+++

7,013

65,686

368,498

75.2

(+++)

3,970

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Impacts

Reduction of PM emissions (kt)

External cost savings - emissions (billion

EUR)

External cost savings - noise (billion

EUR)

Free movement of persons and goods

(GO3)

Removal of obstacles to re-registration of

vehicles in another MS

Removal of obstacles related to the

roadworthiness testing

Update of roadworthiness testing (SO1)

Roadworthiness of vehicles (incl. electric)

in terms of their road safety performance

Roadworthiness of vehicles in terms of

their environmental performance

Reducing

tempering,

improving

detection of defected vehicles (SO2)

Reduction defective and tampered

vehicles in terms of emission control

systems

Reduction of vehicles with tampered

emission/noise control system

Reduction of odometer tampering

Benefits due to reduction of odometer

tampering (billion EUR)

Electronic storage and exchange of

vehicle identification and status data

(SO3)

Reduction of time/costs related to the

access and exchange of relevant vehicle

data:

- Cost savings for authorities (billion

EUR)

- Cost savings for PTI centres (billion

EUR)

Efficiency

Coherence

Subsidiarity and proportionality

PO1a

135

58.7

(++)

0.2

(0/+)

PO1b

196

75.2

(+++)

7.3

(++)

PO2

199

76.1

(+++)

7.3

(++)

PO3

199

76.1

(+++)

7.8

(++)

(+)

(++)

(+++)

(+)

(+++)

(++)

(+++)

(0/+)

(+++)

118.3 (businesses

owners)

65.7 (consumers)

(+)

(+++)

118.3 (businesses

owners)

65.7 (consumers)

(++)

(+++)

118.3 (businesses

owners)

65.7 (consumers)

(+++)

118.3 (businesses

owners)

65.7 (consumers)

(+++)

(+)

(+++)

0.64

1.43

+++

0.64

0.0

0.64

1.43

+++

0.64

1.43

Source: Ricardo et al. (2024), Impact assessment support study

7.5.

Sensitivity analysis

Sensitivity analysis on contribution of technical defects to road crashes and share of high emitting

vehicles of air pollution and noise in the fleet.

As indicated in section 6.2.1, there is significant uncertainty

around the contribution of technical defects to road crashes. The central assumption used is that 4% of road

crashes are caused by technical defects in the case of cars, vans, heavy duty vehicles and trailers and 6% in

the case of motorcycles. A sensitivity analysis has been performed to understand the implications of lower

or higher contribution of technical defects to road crashes. The following cases have been assessed:

Low case: 3% for motorcycles and 1% for all other categories;

High case: 9% for motorcycles and 7% for all other vehicle categories.

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In addition, considering the uncertainty of the share of high emitting vehicles of air pollution and noise in

the fleet, the implications of alternative shares of high and low emitters in the baseline scenario have been

assessed. More specifically, compared to the central case the following assumptions have been used:

Low case: shares of high emitters 25% lower than in the baseline;

High case: shares of high emitters 25% higher than in the baseline.

Subsequently, the impacts on external costs and the efficiency of the policy options is assessed for the low

and high case, including both elements related to safety and emissions.

Table 29 presents the impacts on total benefits, net benefits and benefits to costs ratio by policy option in

the low case, central case and high case. It shows that all policy options are expected to result in net benefits

under the three cases considered. It also shows that the ranking of the policy options is not expected to

change in the low case and high case relative to the central case estimates. More details on the sensitivity

analysis, including the details on the external costs by type, are provided in Annex 4 (section 7).

Table 26: Summary of costs and benefits of the policy options in the low case, central case and high case, expressed

as present value over 2025-2050 compared to the baseline (in million EUR, in 2022 prices)

Difference to the Baseline

PO1a

Total costs

Total benefits

Low case

Central case

High case

Net benefits

Low case

Central case

High case

Benefits to costs ratio

Low case

Central case

High case

38.7

40.8

43.5

5.3

5.9

6.5

5.3

5.9

6.6

5.2

5.8

6.4

275,041.5

290,575.3

310,459.3

282,184.7

321,929.3

362,810.5

285,437.6

325,674.4

367,029.4

286,631.5

327,503.3

369,507.9

282,344.8

297,878.6

317,762.6

347,977.0

387,721.5

428,602.8

351,341.5

391,578.3

432,933.3

355,230.4

396,102.2

438,106.8

7,303.3

PO1b

65,792.3

PO2

65,903.9

PO3

68,598.9

Source: Ricardo et al. (2024), Impact assessment support study

Sensitivity analysis on odometer fraud.

As explained in sections 6.1.2.4 and 6.1.3, it should be

acknowledged that there is uncertainty regarding the economic damage caused by odometer fraud and the

number of vehicles affected. For this reason, sensitivity analysis has been performed on the economic

damage caused by odometer fraud and the number of vehicles affected.

With regard to the economic damage caused by odometer fraud,

a central estimate of EUR 2,119 per

vehicle has been used and it is explained in more detail in Annex 4 (section 2). The following cases have

been assessed:

Low economic damage case: 20% lower damage costs/costs savings per vehicle (EUR 1,696 per

vehicle);

High economic damage case: 20% higher damage costs/costs savings per vehicle (EUR 2,543 per

vehicle).

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With regard to the number of vehicles affected,

the central assumptions used for the shares of vehicles with

tampered odometers are provided in Annex 4 (section 2), Table 37. The following cases have been assessed:

Fewer vehicles affected case: share of affected vehicles 20% lower than in the central case;

More vehicles affected case: share of affected vehicles 20% higher than in the central case.

In addition, the

combined impact of the economic damage caused by odometer fraud and vehicles affected

has been assessed as follows:

Low economic damage and vehicles affected case: 20% lower damage costs/costs savings per

vehicle (EUR 1,696 per vehicle) and the share of affected vehicles 20% lower than in the central

case;

High economic damage and vehicles affected case: 20% higher damage costs/costs savings per

vehicle (EUR 2,543 per vehicle) and the share of affected vehicles 20% higher than in the central

case.

Subsequently, the impacts on the benefits due to avoided odometer fraud and the efficiency of the policy

options is assessed for the low case and for the high case. In this section, only the combined impact of the

sensitivity analysis for economic damage caused by odometer fraud and vehicles affected is presented. The

results of the separate sensitivity analysis for the economic damage caused by odometer fraud and for the

number of vehicles affected is presented in Annex 4 (section 7).

Table 27 presents the impacts on total benefits, net benefits and benefits to costs ratio by policy option in

the low economic damage and vehicles affected case, central case and high economic damage and vehicles

affected case. It shows that all policy options are expected to result in net benefits under the three cases

considered. It also shows that the ranking of the policy options is not expected to significantly change in the

low economic damage and vehicles affected case and high economic damage and vehicles affected case

relative to the central case estimates. More details on the benefits due to avoided odometer fraud in each

case are provided in Annex 4 (section 7).

Table 27: Summary of costs and benefits of the policy options in the low economic damage and vehicles affected

case, central case and high economic damage and vehicles affected case, expressed as present value over 2025-

2050 compared to the baseline (in million EUR, in 2022 prices)

Difference to the Baseline

PO1a

PO1b

PO2

PO3

Total costs

7,303.3

65,792.3

65,903.9

68,598.9

Total benefits

Low economic damage and vehicles

231,635.9

321,478.8

325,335.2

329,859.5

affected case

Central case

297,878.5

387,721.5

391,577.8

396,102.1

High economic damage and vehicles

378,841.8

468,684.7

472,541.1

477,065.4

affected case

Net benefits

Low economic damage and vehicles

224,332.5

255,686.6

259,431.3

261,260.6

affected case

Central case

290,575.2

321,929.2

325,674.0

327,503.2

High economic damage and vehicles

371,538.5

402,892.5

406,637.2

408,466.5

affected case

Benefits to costs ratio

Low economic damage and vehicles

31.7

4.9

4.8

affected case

Central case

40.8

5.9

5.8

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PO1a

High economic damage and vehicles

51.9

affected case

Source: Ricardo et al. (2024), Impact assessment support study

Difference to the Baseline

PO1b

PO2

7.1

7.2

PO3

7.0

REFERRED OPTION

8.1.

Identification of the preferred policy options and stakeholder views

Each of the policy options addresses the problems identified, their drivers and the specific objectives,

however some options are more effective in achieving the specific and general objectives. As indicated in

the previous sections, PO3 is the most effective option, as it performs best or among the best under all

assessment criteria (cf. Annex 9), since it aims to fill most regulatory gaps. It is followed very closely by

PO2, with PO1b and PO1a being less effective (especially PO1a at least in terms of bringing quantifiable

benefits). The fact that PO1a and PO1b perform less well on certain aspects is due to their focus on better

exchange of data (PO1a) and on better testing (PO1b), while PO2 and PO3 combine the key measures of

the first two options. While PO1b performs very well in relation to the objectives of improving road safety

(GO1) and reducing the number of high-emitting vehicles (GO2), PO1a does so in terms of improving free

movement (GO3). The advantages of PO2 and PO3 become clear when comparing the options against the

specific objectives, where they achieve high scores while PO1a and PO1b are limited by their specific focus.

PO1a is the least effective, especially in relation to specific objectives SO1 and SO2.

On the other hand, in terms of efficiency, PO1a performs much better as it generates the lowest costs, while

PO1b, PO2 and PO3 are more costly but also bring more benefits. PO1a is the most efficient option, with

benefits to costs ratio estimated at 40.8. PO1b, PO2 and PO3 show very similar benefits to costs ratio (5.8

to 5.9). In terms of net benefits that can be quantified, PO1b, PO2 and PO3 perform significantly better

than PO1a, while the quantifiable differences among these three options are relatively limited (they are

essentially down to the measures extending PTI or RSI to relatively smaller groups of vehicles). In addition,

compared to PO1b, PO2 brings cost savings for PTI centres due to improved data governance, as well as

increased and more accessible data for authorities and inspection centres in PO2 as compared to PO1b

which facilitates re-registration and roadside inspections. The efficiency and the net benefits of PO2 and

PO3 would further increase compared to PO1b if the benefits related to achieving the objectives related to

free movement (GO3) could be quantified. PO2 appears to strike the best balance between achieving the

objectives to a high degree, while performing at better the other options in terms of internal and external

coherence (by combining the most important measures of PO1a and PO1b while not having issues with

external coherence as PO3), as well as in terms of subsidiarity and proportionality (by including only what

is most needed to achieve the objectives).

While all options include the most efficient policy measure (PMC9 addressing odometer fraud), which offer

very high benefits compared to limited costs, only PO1b, PO2 and PO3 feature relatively costly measures

that introduce new testing requirements. Among them, the mandatory yearly testing of vehicles older than

10 years generate the highest costs, but also the largest benefits, both in terms of road safety and emission

reductions. Crucially, this measure also generates a significant number of jobs, especially in Member States

where the automotive industry is facing historical challenges. Comparatively, the measures differentiating

between PO2 and PO3 are less significant, albeit still relevant. The detailed costs and benefits of those

measures are outlined in Annex 4, section 5 and 6.

PO2 addresses all identified issues in a comprehensive manner by adapting roadworthiness testing to new

vehicles with a capability of identifying a significant share of high-emitters and various forms of tampering,

including odometer fraud with the help of digitalisation and better exchange of vehicle data. What PO2 does

not do in comparison to PO3 is mandatory PTI for all motorcycles, trailers, including lighter ones, and the

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full recognition of PTIs conducted in another Member State with further harmonisation of test methods.

While these measures could bring further benefits, they appear to be limited in comparison to the costs and

additional administrative efforts required, and thus lower the efficiency of PO3. In relation to the well-

established national policies in the field, PO3 also appears to be less coherent than PO2, and regarding the

full recognition of PTI certificates, PO3 could be going beyond what is necessary to reach the

objectives and it may not be compatible with existing structural differences of PTI testing setup in

the Member States.

The analysis above points at PO2 as the preferred policy option,

given it is considered effective

in reaching the policy objectives, it presents high efficiency and net benefits and it appears to be

coherent with the well-established national policies in the field, while including in its set of measures

only those which are needed to achieve the objectives.

The preferred option enjoys the support of the PTI industry (CITA, FSD and others) as well as FIA, testing

equipment (EGEA) and motorcycle manufacturers (ACEM). It is supported also by some Member States,

notably those that rely on thousands of smaller roadworthiness testing centres. Regarding access and

exchange of information, various respondents (including CITA, EGEA and EReg), underlined the

importance of free and easy access to in-vehicle data to enable the proper inspection of vehicles.

Stricter cargo securing requirements included in this option are strongly supported by the logistics industry.

Various industry respondents, including PTI operators, called for the extension of the PTI Directive

to cover all road vehicles. While stakeholders belonging to motorcyclists’ groups at EU or national

level did not support such extension of the PTI to motorcycles in the OPC, in the survey most of the

respondents supported mandatory PTI for motorcycles with the objective to reduce tampering and

the detection of defected vehicles. Stakeholders also noted that many Member States already required

a PTI for motorcycles, as well as for tractors and/or trailers.

All policy options include mandatory testing after significant modification of a vehicle, which was

supported by stakeholders in the survey. Regarding the increased frequency of testing, PO2

introduces annual emission testing for vans, and it also contains a requirement for an annual PTI for

vehicles over 10 years old, both these measures being supported by a majority of stakeholders in the

survey.

Regarding the recognition of PTIs conducted in another Member State, PO3 introduces a full

recognition, while PO2 requires the recognition of the PTI from another MS than the MS of

registration for a period of up to 6 months. Stakeholder views on this differ to quite some extent:

vehicle owners and those not directly involved in PTI inspections tended to be more in favour of the

mutual recognition of PTI certificates under certain conditions, although some recognised that the

mutual recognition under bilateral agreements would be a good first step. Those more actively

involved with inspections were concerned that the difference between the approach taken to PTIs in

different Member States meant that mutual recognition would be difficult and potentially lead to

adverse effects on safety. Concerns were also raised that mutual recognition without the increased

harmonisation of PTIs would lead to “PTI tourism”, where drivers had their vehicles tested in

countries where it was easier to pass a PTI.

All policy options tackle odometer tampering. New methods for tackling odometer fraud were

considered as necessary by 69% (107) respondents in the OPC and adding odometer data to the

vehicle register was welcomed by 72% (111) respondents in the OPC. In the consultations, in relation

to odometer readings, some stakeholders suggested that it should be mandatory to record odometer

data at certain events, such as following accidents and the transfer of ownership, and that potential

buyers should have access to all this information. Not all stakeholders were however positive about

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this measure: some called on odometer system manipulation to be addressed via type-approval

legislation, rather than the revision of the PTI Directive (FIA), and others questioned the potential

inclusion of new methods to tackle odometer fraud, arguing that inspection organisations did not

have the legal means or ways to detect and sanction such fraud (CITA).

Regarding the content of RSI, a majority of respondents (81% and 77% respectively) thought that

PN testing for commercial vehicles and NO

and noise testing for all vehicles using remote sensing

would improve the detection of defective vehicles and reduce tampering. In the OPC, a small majority

supported extended emission testing (e.g., NO

and PN), including the use of remote sensing

equipment, during RSI. Regarding cargo securing, there was a high level of support for mandatory

checks during roadside inspections of commercial vehicles to ensure the safe securing of cargo,

expressed in the survey and OPC.

In relation to introducing RSI to light commercial vehicles, around three quarters of respondents

thought that the extension of the scope of the RSI to light commercial vehicles would contribute to

better detection of defective and tampered vehicles, but some stakeholders also suggested that this

could bring additional costs, in terms of lost time, for SMEs operating such vehicles.

Regarding access and exchange of information/data, two-thirds of respondents in OPC supported

clarifying the existing rules on access to in-vehicle data. Vehicle and equipment

manufacturers/suppliers were less supportive of this provision than others. In response to the open

survey and interview questions, various respondents (including CITA, EGEA and EReg), underlined

the importance of free and easy access to in-vehicle data to enable the proper inspection of vehicles.

Finally, all policy options include measures aimed at facilitating exchange of PTI and registration

data. PO1a, PO2 and PO3 furthermore introduce measures on the digitalisation of registration

certificates and new data sets to be included. A large majority of stakeholders supported these

measures. National authority respondents highlighted that 17 Member States already used Eucaris

for the purpose of data exchange, and that this system worked well. They underlined that data on the

vehicle register should be harmonised and available to all organisations that were involved in

undertaking PTIs and RSIs for national authorities. EReg called for a larger set of data to be included

in the vehicle register and generally supported the digitalisation of the vehicle registration documents

and the mutual recognition of these. Various national authorities, and users, underlined the

importance of the data in the vehicle register being up to date as soon as relevant changes happen.

More details on stakeholder views are provided in Annex 2.

8.2.

REFIT (simplification and improved efficiency)

This initiative is included in the Commission Work Programme 2023

241

, item 3 in Annex II: REFIT

initiatives, under headline A – A European Green Deal. It contributes to increasing the efficiency of the

existing legislation in various ways: by replacing obsolete test methods with stat-of-the art solutions both at

periodic as well as at roadside checks by requiring to use the most recent measurement techniques and

technology to more effectively detect a large number of high-emitting vehicles; by introducing simple,

nevertheless meaningful tests to check the safety and environmental performance of modern vehicles in a

harmonised way; by interconnecting national databases to help share and access vehicle data that otherwise

would be exchanged using more cumbersome procedures. The initiative is expected to significantly reduce

fraud related to emission and safety-relevant systems as well as to the stated mileage of used vehicles

241

2023 Commission work programme – key documents (europa.eu)

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especially in cross-border sales and would thus lead to significant savings in external costs as well as in

avoided damage to consumers.

8.3.

Application of the ‘one in, one out’ approach

PO2 is expected to lead to administrative costs for PTI centres and vehicle manufacturers due to the measure

on data governance (PM11), and for garages, motor vehicle dealers, tyre service and repair stations due to

the measure on odometer readings (PMC9).

For PTI centres,

the one-off administrative costs for the adaptation of their IT systems are estimated at

EUR 1,000 per centre. Total one-off administrative costs would amount to EUR 48.9 million in 2026, for

the 48,880 PTI centres across the EU. The recurrent administrative costs for the maintenance of the IT

systems are estimated at 10% of the capital costs, or EUR 100 per PTI centre. Total recurrent administrative

costs are thus estimated at EUR 4.9 million per year from 2026 onwards.

Vehicle manufacturers

will also need to adjust their own IT systems to ensure access to the relevant data.

The one-off costs are expected to be around EUR 1 million per vehicle manufacturer, with total one-off

administrative costs of EUR 20 million in 2026 for the 20 vehicle manufacturers across the EU. Recurrent

administrative costs are estimated at 10% of the capital costs or EUR 100,000 per vehicle manufacturer.

For the 20 vehicle manufacturers, they amount to EUR 2 million per year from 2026 onwards.

The costs for the garages, motor vehicle dealers, tyre service and repair stations

will relate to possible

software updates to allow them to transfer their data to the central national database, maintenance costs for

the software and the time needed to record the odometer readings. Based on input from Car-Pass and the

European Parliament study

242

, the costs for software updates are estimated at EUR 229 per garage in 2022

prices

243

. In PMC9 these costs are relevant for 651,351 companies (470,765 repair shops and garages across

the EU and 180,586 motor vehicle dealers)

244

, excluding those in Belgium and the Netherlands, which

implemented the measure already and are part of the baseline. Total one-off administrative costs are thus

estimated at EUR 149.2 million in 2026. In addition, for the purpose of the

‘one in one out approach’,

the

average annual recurrent administrative costs over 2026-2035 are estimated at EUR 19.5 million per year

245

or EUR 29.9 per company.

In total, the additional one-off administrative costs relative to the baseline relevant for the ‘one in one

out approach’ in PO2 are estimated at EUR 218 million in 2026. Expressed as annualised net present

value over the relevant period they amount to EUR 25.5 million. In addition, the recurrent

administrative costs relative to the baseline amount to EUR 26.4 million per year. Thus, the total

additional administrative costs (one-off and recurrent) relevant for the ‘one in one out approach’ in

PO2 are estimated at EUR 51.9 million per year relative to the baseline. Other administrative costs for

citizens and businesses (i.e., vehicle owners) in PO2 relate to additional periodic technical inspections and

cooperating on roadside inspections with the public authorities and are thus not subject to the

‘one in one

out approach’.

242

European Parliament (2018), Odometer Manipulation in motor vehicles in Europe,

https://www.europarl.europa.eu/RegData/etudes/STUD/2018/615637/EPRS_STU%282018%29615637_EN.pdf

243

The cost was estimated at EUR 200 per garage in 2018 prices. Using the harmonised index of consumer prices (HICP)

from Eurostat, this is equivalent to EUR 229 per garage in 2022 prices.

244

Eurostat, Structural business statistics, Enterprise statistics by size class and NACE Rev.2 activity.

245

This is calculated as a simple average over 2026-2035, non-discounted.

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OW WILL ACTUAL IMPACTS BE MONITORED AND EVALUATED

The Commission services will monitor the implementation and effectiveness of this initiative through a

number of actions and a set of core indicators that will measure progress towards achieving the operational

objectives. Five years after the revised legislation will have been applied, the Commission services should

carry out an evaluation to verify to what extent the objectives of the initiative have been reached.

Road safety:

the Commission regularly monitors key road safety indicators, including the evolution of the

number of fatalities, serious and slight injuries per Member State and per vehicle category, age and certain

vehicle characteristics. Detailed information on the causes of crashes, notably on vehicle defects is unlikely

to become available at large scale soon. In the future, analysis of event data recorders mandated by the

General Safety Regulation may provide more detailed insight into the causes of a significant share of

crashes. Until then, existing reporting requirements should be updated to better respond to current

monitoring needs, as outlined in Annex 15.

Similarly, the evolution of

air and noise pollution

is continuously monitored by the EEA. Part of the

reduction expected over the years to come will be related to this initiative through better maintenance of

vehicles and reduced tampering with emission control systems. Progress towards the objective of

contributing to sustainable mobility can be measured through the evolution of PTI and RSI results, as well

as from remote sensing data. As for

facilitating free movement,

indicators of success will be the number of

Member States recognising PTIs conducted abroad.

To measure the success of the initiative, the following operational objectives are set: 1) Apply newly

available safety and emission testing methods; 2) Interconnect Member States’ vehicle registers and

odometer databases through a common hub; 3) Digitalise vehicle documents; 4) Reduce the number of

defective and tampered vehicles on EU roads. Indicators to monitor progress towards these objectives are

defined in Annex 15.

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NNEX

1: P

ROCEDURAL INFORMATION

EAD

DG, D

ECIDE

LANNING

/CWP

REFERENCES

The lead DG is Directorate General for Mobility and Transport (MOVE), Unit C2: Road Safety

DECIDE reference number: PLAN/2021/10932

This initiative was referred to in point 16 of the Sustainable and Smart Mobility Strategy. Action 7

in the Action Plan called for improved emission testing in roadworthiness tests. Action 66 called on

the Commission to assess the need for a proposal to require efficient exchange of odometer readings

across the EU.

This initiative is included in the Commission Work Programme 2023

246

, item 3 in Annex II (REFIT

initiatives), under headline A – A European Green Deal.

RGANISATION AND TIMING

The impact assessment and the ex-post evaluation of the Roadworthiness Package were performed

in a back-to-back manner (i.e., the evaluation and impact assessment have been launched at the same

time) in 2021-2023.

The combined evaluation roadmap/inception impact assessment was published on Have your say on

4 October 2021

247

. The ex-post evaluation and the impact assessment on a possible review of the

Roadworthiness Package were coordinated by an Inter-Service Steering Group (ISG). The

Commission Services participating in the ISG were: Secretariat-General, Legal Service, Directorates-

General GROW, RTD, CLIMA, ENV, JRC, CNECT, EMPL, JUST. The ISG met 6 times: 22

September 2021, 14 December 2021, 8 July 2022, 24 November 2022, 9 October 2023 and 9

November 2023. It was consulted throughout the different steps of the evaluation and impact

assessment process: notably on stakeholder consultation questionnaire and deliverables of the

external support study and on the draft Staff Working Documents. When necessary bilateral

discussions were organised with the concerned services.

ONSULTATION OF THE

RSB

The draft impact assessment and evaluation reports were submitted to the RSB on 20 November 2023

and were discussed by the Board on 13 December 2023. The RSB issued a positive opinion with

reservations on 15 December 2023. The recommendations from the Board have been addressed in

this final version of the Impact Assessment report as detailed in the table below.

Table 28: Modifications of the impact assessment report in response to RSB recommendations

RSB recommendations

Modifications to the IA report

Main considerations

(1) The report is not sufficiently clear about the Theses aspects have been clarified in section 2

scale of the problem, the robustness of the of the impact assessment, as explained below

underlying evidence and the assumptions made under (1) and (2).

in the analysis.

246

247

2023 Commission work programme – key documents (europa.eu)

Vehicle safety – revising the EU’s roadworthiness package (europa.eu)

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(2) The report does not clearly explain the

reasoning behind the packaging of options. It

does not sufficiently bring out the key policy

choices and the related trade-offs, including in

terms of reduced fatalities and injuries. The

costs and benefits implications of key safety

measures are not clearly presented.

The packaging of the options and the trade-offs

were revisited and clarified, and are further

described under points (3), (4), and (5) below.

The costs and benefits are now further detailed

in Annex 4 (e.g. in new section 6) and better

explained also in the comparion of options.

(3) The comparison of options is not sufficiently The comparison, including re ‘Vision Zero’ has

detailed and nuanced, including in terms of been further detailed as described under point

coherence with the ‘Vision Zero’ road safety (6) below.

policy framework.

Adjustment requirements

(1) The report should make clear what the scale

of the problems identified is, including

regarding vehicles currently exempted, such as

motorcycles, or not subject to a yearly PTI, such

as vehicles older than 9 years. The strength and

robustness of the evidence underpinning the

analysis of the problems and impact analysis

and of related estimations should be made more

explicit. The report should clarify supporting

assumptions when it comes to the contribution

of defects in vehicles to road crashes and the

link between road safety and inspections. The

geographical distribution of the problems

identified should also be better explained, with

clear references to the situation in different

Member States.

(2) The report should more clearly acknowledge

any uncertainties related to the evidence and

assumptions used, in particular in relation to the

analysis of the impacts of the odometer fraud

measure. A sensitivity analysis should be

carried out to show how these limitations affect

the overall cost-benefit analysis (looking for

instance at the assumptions on the number of

cars affected and the economic damage caused

by odometer fraud).

The report should be clearer about the

assumptions used and why different data points

(lower bound in some cases) were selected for

the estimations. It should also clarify to what

extent key assumptions were validated by

independent experts and represent the state of

the art on this matter. Similarly, the report

should clarify the scale and geographical

The scale of the problem of unsafe and polluting

vehicles has been explained in more detail,

including geographical details, in section 2.1,

2.2 and 2.2.5. The level of confidence in the

underpinning evidence has been clarified and

backed by additional sensitivity analysis.

Further details as regards the underlying

assumptions and calculations are described

sections 4 and 5 of Annex 4 (impact on road

safety and emissions of individual measures and

policy options).

The uncertainty regarding the economic damage

caused by odometer fraud and the number of

cars affected is acknowledged in section 6.1.2.4

and section 6.1.3. Sensitivity analysis has been

performed on the assumptions on the economic

damage caused by odometer fraud and the

number of cars affected, and its impacts in terms

of overall cost-benefit analysis are reported in

section 7.5 and Annex 4 (section 7).

The calculations of the costs for measure PMC6

(Require roadworthiness certificate in electronic

format only) have been revised to account for

the volumes of inspections per Member State

instead of using the lower bound of the

estimates provided during the stakeholders

consultation. The evidence underlying the

problems and their drivers, as well as the

assessment of impacts, is based on the best

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distribution of the problem when it comes to

older cars, lighter vehicles and mopeds not

being (sufficiently) tested for roadworthiness

and the consequences of this.

available evidence, including multiple studies

involving scientific research, as well as

thorough consultation with experts. This has

been further emphasised in section 2 and section

6. Additional sensitivity analysis has also been

performed and is reported in section 7.5 and

Annex 4 (section 7).

The scale and geographical distribution of the

problem of older vehicles and powered two- and

three-wheelers is clarified as explained above

(1).

(3) The report should explain more clearly the

reasoning behind the packaging of options. It

should clarify why certain policy measures,

such as recording the odometer reading or

registration of certificates in digital formats are

not included in all policy packages. Given that

the policy measure aimed at tackling odometer

fraud is expected to bring by far the most

significant net benefits, excluding this measure

in some policy packages would make them

underperforming by design. The report should

provide a clear justification why this key

measure should not be included in the set of

measures common for all options. If an

exclusion can be convincingly argued, the report

should present variants for options 1a/b

including the odometer measure to allow a fairer

and more balanced comparison of options.

(4) The report should explain the reasoning

behind advocating a non-binding measure for

the testing of powerful motorcycles, despite its

more limited potential beneficial impact on road

safety. The explanation should also clarify why

a non-binding measure is considered as an

adequate measure exclusively in the safety case

of powerful motorcycles but not for any other

road safety problem area. When substantiating

this reasoning, the report should make clear

references to the evidence available from

different Member States (which are currently

applying a testing regime and which are not and

what a non-binding or binding EU measure on

this would bring)

Following the comments received from the

Board, the measure on recording the odometer

reading has now been included in all policy

options. In addition, the mandatory yearly

testing for vehicles that are 10-year-old or older

(PM6) is now included in PO1b, PO2 and PO3.

The changes are reflected in sections 5.2.

Following the observations of the Board, the

measure in question (PM1 – roadside inspection

of motorcycles as an alterantive to PTI) has been

revised. It is now presented as a binding

measure, which indeed corresponds to the

relvant calculations in terms of costs and

benefits. The changes are reflected in sections

5.2, 6.1, as well as in the Annexes.

(5) The report should present better the key The benefits of the measures were indeed

policy choices and related trade-offs, in assessed as part of the policy options,

particular regarding the benefits and costs of considering also the synergies between them.

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several key road safety measures, including the

mandatory yearly testing for older vehicles and

the ending of the exemptions of motorcycles and

light trailers. These measures are currently

included as a bundle and assessed together only

in the most ambitious option package 3.

However, a complementary measure-by-

measure benefit-cost assessment should allow

the identification of potentially net beneficial

measures in terms of overall reduced fatalities

and injuries. As these are highly relevant for

decision-making, the report should bring them

out more clearly.

Their costs,

individually.

however,

were

calculated

The estimated impacts (in terms of lives saved

and external costs savings) of the options have

now been split to show the impact of the

relevant individual measures.

The expected cumulative reduction in the

number of fatalities and injuries by policy

option and policy measure is now included in

section 5 of Annex 4. In addition, the trade-offs

regarding the costs and benefits of those policy

measures are presented in a new section 6 of the

same annex.

In section 7, a more detailed presentation of the

key impacts (costs and benefits), both

quantifiable and qualitative, has now been

included.

The comparison of effectiveness now focuses

on achieving the specific objectives, while the

limited differences in coherence between PO2

and PO3 are also explained in section 7 and

Annex 14.

Table 25 has been replaced with a detailed

overview of the key impacts as requested.

In section 8, the differences and trade-offs

between the revised options are clarified in

relation to the three criteria.

(6) The comparison of the revised set of options

needs to be more nuanced and granular. To

allow a more coherent effectiveness comparison

of options the report should present one clear set

of specific objectives avoiding overlaps with the

general objectives. Regarding coherence, the

report needs to demonstrate why packages 2 and

packages 3 are scored the same, despite the

significant differences with respect to

contribution to the Vision Zero road safety

goals. The comparison overview Table 25

should be reworked to allow a detailed overview

of quantitative and qualitative key impacts, so

that the key differences between the options

become more obvious. On this basis, the report

should better justify the choice of the preferred

option, while being clear on the key trade-offs

between options in terms of efficiency,

effectiveness and coherence.

VIDENCE

SOURCES AND QUALITY

The impact assessment and evaluation are based on several sources, using both quantitative and

qualitative data, collected from Member States, industry, and other EU bodies. This includes:

•

Stakeholder consultation activities (see dedicated annex);

Regular meetings of the Expert Group on Roadworthiness and Vehicle Registration

Documents (RWEG);

External support studies carried out by independent consortia (the study supporting the

evaluation was led by VVA and the one supporting the impact assessment was led by

Ricardo). The external support studies will be published alongside this report;

Ad-hoc consultation of industry experts; and

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•

The Commission’s own experience in monitoring and implementing the Roadworthiness

Package.

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NNEX

2: S

TAKEHOLDER CONSULTATION

YNOPSIS REPORT

)

This stakeholder consultation synopsis report provides a summary of the outcomes of the stakeholder

consultation activities which were carried out as part of this back-to-back evaluation and impact

assessment in view of a possible revision of the Roadworthiness Package (RWP). It provides a basic

analysis of the responses of stakeholder groups involved in the consultation process and a summary

of the main issues which they raised. The full analysis of the consultation results is presented in the

stakeholder consultation reports annexed to the two external support studies. The same report is

included in the evaluation SWD and in the impact assessment SWD, as an annex to both reports.

Stakeholder involvement was vital for the evaluation and impact assessment in order to collect facts,

data and opinions enabling the Commission to:

•

On the one hand, assess the performance of the RWP against the five evaluation criteria, identify

possible issues with the existing legal framework and, on this basis, learn lessons for future

action;

On the other hand, (i) substantiate, validate and develop the problems and the underlying drivers,

(ii) conceive corresponding policy objectives, (iii) elaborate a list of specific possible policy

measures and policy options and (iv) assess their likely impacts on the various categories of

stakeholders.

•

This report also aims at informing stakeholders on how their input has been considered.

This document should be regarded solely as a summary of the contributions made by stakeholders in

the various consultation activities on the back-to-back evaluation and impact assessment in view of

a possible revision of the Roadworthiness Package (RWP). It cannot in any circumstances be

regarded as the official position of the Commission or its services. Responses to the consultation

activities cannot be considered as a representative sample of the views of the EU population.

VERVIEW OF CONSULTATION ACTIVITIES

Consultation activities took place from October 2021 to August 2023.

The consultation strategy set different focuses for the consultation activities for the evaluation and

the IA to complement each other. The evaluation related survey and targeted interviews gathered

stakeholders’ views and input on the selected evaluation questions and evaluation criteria. They are

complemented with the views expressed at the OPC.

The focus of the survey and interviews for the IA were on defining the different policy measures to

meet the objectives set as part of the revision of the Roadworthiness Package, particularly the costs

and potential impacts of these policy measures. The underlying problem drivers of the RWP were

extensively discussed with stakeholders, e.g. in the Roadworthiness Expert Group and are also a

result of the stakeholder consultation activities of the evaluation. Having said that, both the survey

and interviews did briefly cover the baseline, problem drivers and objectives, as well as potential

impacts of the measures, so on all parts of the IA.

The stakeholder consultation included the following activities:

•

Targeted online survey for the evaluation:

two online surveys were conducted targeting the

stakeholders identified at the inception stage of the Evaluation Study and covered the 5 evaluation

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criteria of relevance, effectiveness, efficiency, coherence and EU value added. It was launched on

8 December 2022 and ran until 20 January 2023. One survey targeted relevant EU associations,

relevant ministries of EU Member States, road safety authorities and OEMs; In total 38 responses

were received: 17 from ministries and road safety authorities, 16 from EU associations, consumer

organisations and NGOs, 5 from vehicle registration authorities. The other survey was addressed

to PTI bodies and 11 responses were received.

•

Targeted semi-structured interviews for the evaluation

sought to explore the respondents’

views on the RWP for each evaluation question defined. They took place in the period between

November 2022 and April 2023. The interviews were conducted with representatives from 30

selected technical or policy related organisations including national registration authorities,

technical inspection bodies, the Roadworthiness Committee, the Roadworthiness Expert Group

and road safety and environmental NGOs. They were selected in order to gather additional

evidence, to ensure geographical coverage and to increase the sample size in a group of

interviewees by stakeholder type.

Exploratory interviews for the IA.

The aim of the exploratory interviews was to obtain early

engagement with key stakeholders (including authorities, industry and user representatives).

Introductory calls were made with key stakeholders, i.e. CITA, EReg, CORTE and EGEA, to

discuss the engagement of these organisations and their members with the initiative, including the

distribution of the survey and the identification of potential interviewees. In addition, user groups,

such as FIA (car drivers), IRU (lorry drivers) and FEMA (motorcyclists), were informed about

the initiative and were interviewed as well.

Targeted online survey for the IA.

The focus of the survey was on the policy measures under

consideration, particularly the details of the measures, their potential costs and savings and

potential impacts. The survey was online between 26 June and 14 August 2023. The survey

targeted national authorities involved in inspection activities at various levels, including policy

development, inspection supervision and enforcement, and industry representatives, including

those that undertake inspections and supply garage equipment and vehicles. 75 responses were

received to the survey.

Targeted stakeholder interviews for the IA.

The majority of interviews were based on the

interviewee’s survey response, with a focus on identifying information on costs. A minority of

interviews were undertaken independent of a survey response, e.g. for those organisations, such

as users and research representatives, for which a survey was less relevant. The interviews began

at the same time as the survey and continued until the end of August 2023. Overall, 37 interviews

were undertaken to refine responses provided in the targeted online survey and to collect evidence

from relevant stakeholders not covered in the survey.

Evaluation roadmap / Inception impact assessment (IIA).

As part of the initial feedback

mechanism, stakeholders had the possibility to provide views on the combined evaluation

roadmap / inception impact assessment published on the “Have your say” webpage between 4

October and 1 November 2021. Responses were received from 210 respondents: 171 from EU

citizens, 9 from business associations, 6 from companies or business organisations, 6 from NGOs,

3 from consumer organisations, 3 from non-EU citizens, 2 from public authorities, 1 from

academia and 9 other. 174 responses were linked to a campaign from predominantly French

citizens, while 36 were unique written responses, that were analysed individually.

Open public Consultation (OPC)

questionnaire, covering both the IA and the evaluation, was

accessible on “Have Your Say” webpage from 6 July to 28 September 2022. 907 replies were

received: 758 from EU citizens, 47 from companies or business organisations, 35 from business

associations, 18 from non-governmental organisations (NGOs), 10 from non-EU citizens, 10 from

public authorities, 5 from trade unions, 3 from consumer organisations, 2 from academic/research

•

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institutions, 1 from an environmental organisation and 18 other.

731 of the responses received

were part of a campaign from predominantly French citizens.

The factual summary report is

available on the consultation page.

TAKEHOLDER GROUPS CONSULTED

This section provides a short overview of the main types of stakeholders identified and targeted as

part of the consultation strategy. Overall, the consultation attracted interest from various types of

stakeholders, which resulted in a good participation level and numerous contributions received. All

identified stakeholder groups have been reached. However, the responses received are not

representative of the EU population.

Table 29: Identification of key stakeholder groups and mapping against consultation activities

High-level

Description

Stakeholder

stakeholder group

engagement activity

Public authorities in

Authorities involved in different activities relating to the RWP, Exploratory interviews

charge of road safety

including vehicle registration, inspection, enforcement and Targeted surveys

policy. Initial engagement was undertaken via their various Targeted interviews

representative associations, such as CITA, EReg and CORTE.

OPC

Call for Evidence

Industry associations

Associations and companies involved in different aspects of Exploratory interviews

and companies

RWP, particularly those involved in inspections and supplying Targeted surveys

equipment to garages. These were engaged with initially via Targeted interviews

their representative associations, such as CITA and EGEA. In OPC

addition, vehicle manufacturers and vehicle component Call for Evidence

suppliers were also contacted.

Representations of

Groups representing the drivers of the various vehicles covered Targeted interviews

user groups

by the RWP were engaged with to identify their views on the OPC

potential measures.

Call for Evidence

Road safety and

The views of specialist NGOs were also sought to ensure that Targeted interviews

environmental

the safety and environmental aspects of the measures were OPC

NGOs

sufficiently considered.

Call for Evidence

Research / academia

Interviews were undertaken with selected road safety academic Targeted interviews

experts.

OPC

Call for Evidence

Citizens

Citizens responded to the combined evaluation roadmap/IIA OPC

and OPC both individually and as part of a campaign, both from Call for Evidence

within and outside the EU.

NALYSIS OF THE KEY RESULTS OF THE STAKEHOLDER CONSULTATION

This chapter presents key findings from the analysis of stakeholder contributions to the consultation

process.

3.1. Feedback received on the EU roadworthiness rules by evaluation criteria

Relevance

•

Survey respondents and interviewed stakeholders generally consider that the

scope and

objectives of the RWP are relevant

as a well-designed legislative package. Interviewed

stakeholders overwhelmingly agree that the three Directives within the RWP are still

thematically relevant to the wider EU policy goals.

However according to the overwhelming majority of survey and interview respondents, there

have been

numerous significant changes in vehicle technology since the RWP came into

•

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effect, which the current RWP does not account for.

There is a

need to adapt the

Directives to environmental and technological developments and digitalisation.

Additionally, according to the respondents, the current measurement methods outlined by the

RWP are considered inadequate for obtaining accurate readings of air pollutants emitted by

vehicles, and traditional smoke opacity testing methods are deemed outdated and insufficient

in detecting various pollutants. Some interviewed stakeholders also emphasise the need to

increase the frequency of inspections for all vehicles due to the growing prevalence of shared

mobility strategies and suggest clarifying certain aspects of testing to make it more targeted.

•

Relevance of the current EU rules on periodic roadworthiness testing and technical

roadside inspections in improving road safety.

Several stakeholder categories, including

academic and research institutions, public authorities, and consumer organisations, who have

participated in the OPC, consider the rules relevant or very relevant in areas such as minimum

standards for testing centres, facilities, and equipment, as well as categorising deficiencies

during periodic tests. However, there are varying opinions from some responding NGOs, EU

citizens, and environmental organisations, who perceive some aspects of the rules as less or

not relevant. In particular, many respondents being part of the campaign consider the periodic

testing of high-speed tractors and heavy motorcycles and applying different time intervals

between periodic tests according to the age of vehicle and vehicle type as less or not relevant.

Relevance of current EU rules on periodic roadworthiness testing and technical roadside

inspections in reducing air pollutant emissions.

Business associations, public authorities,

and trade unions, who participated in the OPC consider the rules relevant in areas such as

establishing minimum standards for testing centres, facilities, equipment, and inspectors'

competence, training, and objectivity. However, there are varying opinions from responding

EU citizens, environmental organisations, and some public authorities, who perceive certain

aspects of the rules as not relevant in reducing air pollutant emissions. In particular, many

respondents being part of the campaign consider the rules related to periodic testing of high-

speed tractors and heavy motorcycles as not relevant for the purpose of reducing air pollutant

emissions.

Relevance of current EU rules on registration documents for vehicles in facilitating free

movement of goods and people within the EU.

The majority of the respondents, who

participated in the OPC, consider the current EU rules to be relevant or very relevant in

facilitating free movement, regarding the obligation on Member States to recognise

roadworthiness certificates upon change of ownership. Views among those who responded

being part of the campaign are more varied.

•

Effectiveness

•

Effectiveness of the current EU rules on periodic roadworthiness testing and technical

roadside inspections in improving road safety

and contributing to the reduction of road

fatalities and serious injuries in road transport in the EU. The majority of respondents, who

participated in the OPC, view the current EU rules as effective in improving road safety and

contributing to the reduction of road fatalities and serious injuries in road transport in the EU

in areas such as establishing minimum standards for testing centres, facilities, and equipment,

categorising deficiencies during periodic tests, obliging Member States to perform roadside

tests on commercial vehicles, and implementing different time intervals based on vehicle age

and type, except for periodic testing of high-speed tractors and heavy motorcycles on which

views are diverging. The respondents participating in the campaign, perceive the current EU

rules on roadworthiness as less or not effective in in certain aspects, such as periodic testing

of high-speed tractors and heavy motorcycles, and minimum standards for inspectors'

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competence, training, and objectivity. The majority of survey respondents and interview

stakeholders agree that PTIs and RSIs helped reduce the number of circulating vehicles with

dangerous defects.

•

The feedback collected from survey respondents and interviewed stakeholders suggests that

vehicles on the road are perceived to have generally been made safer through the introduction

of common standards for testing centres and personnel training, as well as with the adoption

of same rules for frequency, scope and method for vehicle testing. However, interviewed

stakeholders acknowledge that reduction in road deaths witnessed over the past 10 years could

be due to a combination of factors (e.g. gas prices, driver behaviour, infrastructure) and it is

therefore difficult to determine how many accidents are directly caused by mechanical defects

and how many of the lives saved and injuries avoided are specifically linked to PTIs/RSIs.

Effectiveness of current EU rules on periodic roadworthiness testing and technical

roadside inspections in reducing air pollutant emissions.

80 % of public authorities, who

have responded to the OPC, consider as effective the rules regarding minimum standards for

inspectors' competence, training, and objectivity. Respondents in the OPC part of the

campaign, have differing perspectives, with a majority of those respondents viewing the rules

as not effective for the periodic testing of high-speed tractors and heavy motorcycles and for

applying different time intervals between periodic tests, according to the age of vehicles and

vehicle type.

However, interviewed stakeholders also pointed out that not all deficiencies can effectively

be detected by applying the current technical standards for vehicle inspections. Among the

survey respondents and interviewed stakeholders, there is no clear-cut opinion on the extent

to which the provisions of the RWP Package have contributed to reduced air pollutants from

road transport. According to surveyed ministries and road safety authorities, vehicles that

have been tampered with defects which are not covered by the EOBD system or those

specifically related to NOx emissions will not necessarily be detected by the current EU PTI

regimes.

Effectiveness of current EU rules on registration documents for vehicles in facilitating

free movement of goods and people within the EU.

The majority of respondents to the OPC

from public authorities and business associations find the current EU rules effective in

facilitating free movement. On the other side, the participants in the campaign have diverging

opinion on the effectiveness of the current EU rules on registration documents for vehicles in

facilitating free movement.

•

Efficiency

•

Cost-effectiveness of the roadworthiness rules.

Respondents in the targeted survey and the

interviews deemed the

benefits

associated with its implementation generally

proportionate

to the costs,

especially with regards to the improvement of air quality. This is in line with the

views expressed by the survey respondents, who consider that the implementation of the RWP

has generated limited extra costs for authorities, citizens, and businesses. PTI inspections have

not become more expensive, and the use of the EUCARIS system is cost-effective according

to survey respondents. However, certain provisions like OBD checks have incurred costs for

citizens. Ministries, road safety authorities, and EU associations participating in the survey

agree that the benefits of the RWP in terms of road safety and reduced air pollution justify the

costs. EU associations also emphasise its potential in combating illegal pollution and the

human costs of air pollution.

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•

However, while some respondents did not consider RWP provisions as extraordinarily

expensive, others mentioned that the costs associated with installing and upgrading testing

equipment for testing stations is high.

Interviewed stakeholders consider the administrative burden generated by the three Directives

to be smaller for businesses and citizens than for public authorities.

Ministries and PTI bodies, who have participated in the survey, acknowledge that the RWP

and its implementing acts have created to some extents

administrative burden

for public

administration. They emphasise the need for digitalisation in vehicle re-registration to reduce

costs and administrative workload, particularly through data exchange and document

harmonisation. Vehicle registration authorities who have responded to the survey, call for

improved legal provisions and digitalisation to streamline the process. Additionally, EU

associations responding to the survey propose providing type-approval information to PTI

centres without charge.

Most respondents of the survey did not express an opinion on whether the RWP package and

its implementing acts have imposed administrative burdens on businesses. Survey

respondents emphasised the importance of mutual recognition to enhance cost effectiveness

in inspections. They also recommended implementing systems like Car-Pass in Belgium on

an EU-wide scale to address odometer fraud. Furthermore, it was highlighted by them that a

well-assessed test methodology is crucial to avoid inaccurate outcomes in PTI and ensure a

standardised approach to testing procedures and equipment.

The majority of survey respondents did not express an opinion on the administrative burden

imposed by the RWP Directives on citizens. However, EU associations suggested that

implementing mobile vehicle registration documents could enhance the digitalisation of

registration and data management processes, resulting in reduced costs for citizens.

•

Coherence

•

While the Directives comprised in the

RWP are deemed internally coherent by the

interviewed stakeholders,

a few

inconsistencies between the RWP and other road safety

legislations

have been identified by interviewed stakeholders. As a response to the survey a

similar message was passed by responding ministries, road safety authorities, and EU

associations, who acknowledged that to some extent there are inconsistencies, overlaps, and

gaps between the RWP Directives and other EU and international interventions.

According to the interviewed stakeholders the

lack of harmonisation between the PTI and

the type-approval legislations

makes it difficult to perform thorough inspections, as the

number of automated devices, sensors and safety features is growing faster than the PTI

operators’ ability to check them.

The need for consistency between periodic technical inspection (PTI) requirements and type-

approval regulation was also emphasised by the respondents of the OPC. PTI should not go

beyond what is specified in type-approval regulations according to their views. Moreover,

according to OPC respondents, Member States have different conditions and contexts for L-

category vehicles, and they should have the flexibility to determine effective ways to reduce

accidents.

The

Registration Directive and the Type-approval Regulation are not fully consistent

the view of interviewed stakeholders: the fact that each country has the possibility of allowing

a national type-approval with more flexibility than EU type-approval gives some Member

States the chance to be less strict than others, thus raising road safety issues.

•

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•

According to the interviewed stakeholders the General Safety Regulation could better align

with the RWP: for instance, the GSR identifies more responsibilities for manufacturers during

the vehicle’s lifecycle than those foreseen by the PTI legislation.

The feedback received from interviewed stakeholders points to a lack of data coherence,

whereby no one has a holistic view regarding the whole life of the vehicle: from vehicle

definition to vehicle scrapping.

According to the OPC respondents,

standardisation

of rules among EU countries is considered

essential for the effectiveness of the EU technical control package. Disparate rules,

particularly concerning the approval of controllers, need to be addressed in their view.

•

EU added value

•

The EU rules on roadworthiness have added value for citizens and businesses

compared

to what could be achieved by Member States at national and/or regional and international

level according to the respondents to the OPC. There is disagreement among EU citizen

responding to the OPC whether the EU rules on roadworthiness provide added value

compared to what could be achieved at the national, regional, and international levels.

However, there is a significant agreement among academic and research institutions, who

have participated in the OPC that the EU rules do offer added value for citizens and

businesses.

The interviewed stakeholders widely acknowledged the added value of the three Directives

in their contribution towards the harmonisation of roadworthiness rules among Member

States. By setting up minimum standards for carrying out periodical technical inspections and

roadside inspections, the RWP sets up a common framework to identify vehicle deficiencies,

prevent accidents, reduce vehicle emissions and promote fair competition in the field of road

transport.

When expressing views in the survey, ministries, road safety authorities, and PTI bodies

considered that additional EU action is necessary to enhance the RWP and achieve the

objectives of reducing fatalities, serious injuries, and improving air quality through PTI and

RSI inspections in the EU. They emphasised the need for minimum requirements across

Member States to ensure effective PTI and RSI contributing to road safety and air quality.

The overwhelming majority of interviewed stakeholders agree that if the RWP had not been

implemented, the road safety scenario in the EU would be far more fragmented, with Member

States taking greatly differing actions.

•

3.2.

Feedback received on the problem definition

In the

OPC,

respondents were asked for their views on three problems that the revision of the RWP

could address. A majority of respondents – between two-thirds and four-fifths in each case –

supported a revision of the EU’s roadworthiness rules addressing each of the specified problems. The

problem that received most support was the need to address

vehicles circulating on the roads with

defects or tampered components

(78%; 123, six ‘no responses’ or ‘Don’t knows’), followed by

methods for PTI of vehicles to test electronic safety and driver assistance systems in vehicles

(74%;

116, seven ‘no responses’ or ‘Don’t knows’). Two thirds (67%; 100, 14 ‘no responses’ or ‘Don’t

knows’) of respondents also believed that a revision to the legislation should address the

availability

of relevant vehicle data to enforcement authorities in the EU Member States in cross-border traffic.

Themes raised in response to the open questions included that it was important to update inspections

to reflect changes to vehicles and their technology, that it was important to have access to in-vehicle

data to support inspections, that more action was needed to address tampering and that it was

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important to support public authorities in the inspection of foreign vehicles on their roads. Others,

while recognising that changes to inspections were needed, underlined that inspections had to remain

affordable for consumers.

The

survey

produced similar results of support for the revision of the EU’s roadworthiness rules

addressing the different identified problem areas, see Figure 4.

Figure 5: Survey results on stakeholders’ views on identified problems

Source: Ricardo et al. (2023), Impact assessment support study, survey results

In the survey, respondents were asked for their views on more detailed problem areas, and their

associated drivers and on three Specific Objectives (SOs):

•

SO1: Adapt testing to today's and tomorrow's vehicles (improve consistency, objectivity and

quality)

SO2: Significantly reduce fraud and tampering (of safety and emission control systems) and

improve the detection of defective vehicles)

SO3: Improve electronic storage and exchange of relevant vehicle identification and status

data.

There was a high level of agreement – around two thirds or more – for each set of problems and

problem drivers, and overwhelming support (at least 89%) for each of the specific objectives.

Figure 6: Survey results: Stakeholders’ views on identified specific objectives

Source: Ricardo et al. (2023), Impact assessment support study, survey results

Respondents to the

IIA

made a number of general comments about the revision. A common theme

that was raised by those responsible for inspections was the importance of more consideration being

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given to coordinating between type-approval and roadworthiness legislation, and the importance of

maintaining the independence of inspection organisations and inspectors from other parts of the

automotive trade, including repair and maintenance. The importance of a more consistent approach

to roadworthiness testing across the EU was also mentioned.

3.3. Feedback received on the baseline/ existing legislation

In their response to the

survey

and

interview

questions, respondents were often split between those

who believed that the different factors listed had had a high impact on various aspects of

roadworthiness, and those who believed that the impact had been low. The question to which

respondents were mostly having a common view with 75% agreeing (51 of 75; seven ‘Don’t knows’

or no responses) – was in relation to the belief that the

enforcement of roadworthiness legislation

had

had a high impact on the

number of unsafe vehicles

on the EU’s roads since 2014. The majority (60%;

40 of 75; eight ‘Don’t knows’ or no responses) of respondents also felt that

technological and market

developments

had had a high impact on the

number of unsafe vehicles

on the EU’s roads since 2014.

On the other hand, a majority of respondents believed that

technological and market developments

had had a low impact on reducing the

number of vehicles with tampered or defective noise control

systems

(77%; 46 of 75; 15 ‘Don’t knows’ or no responses), or

tampered odometers

(64%; 39 of 75;

14 ‘Don’t knows’ or no responses), since 2014. The responses relating to the impact on the

number

of vehicles with tampered or defective emissions control systems

and the

vehicle re-registration

process

were much more split between those who felt that the impact had been high or low.

Respondents were asked to explain their responses. A common reason listed amongst those

responsible for inspections, as well as users, was the need to update PTIs (and so the PTI Directive)

to take account of the way in which vehicles have developed and will continue to develop. Many of

these respondents also underlined the problem of detecting tampering during a PTI, particularly

tampered odometers.

3.4.

Feedback received on possible solutions

Policy measures: Scope of PTI Directive

The first group of policy measures related to the potential extension of the

scope of the PTI Directive.

In their responses to the

IIA,

various industry respondents, including those organisations responsible

for inspections, called for the extension of the PTI Directive to cover all vehicles that are able to use

roads. For example, In the response for IIA, CITA called for the extension of the scope of PTI to L-

category vehicles and light trailers, as it had undertaken a study that concluded that this would have

a positive cost-benefit impact; it also specified its proposed frequency for inspecting these vehicles.

The French National Council of Automotive Professions (Conseil national des professions de

l'automobile; CNPA) and GOCA Vlaanderen also supported extending the scope of PTI to these

vehicles. The Portuguese National Association of Automobile Inspection Centres (Associação

Nacional de Centros de Inspeção Automóvel; ANCIA) called for testing to be mandatory for all

motor vehicles used on public roads. Inspection company Applus also suggested that the general rule

should be that all vehicles that can circulate on roads in the EU should be covered by the PTI

Directive, although they proposed allowing some exceptions for certain L-category vehicles where

alternative measures were in place. The European Garage Equipment Association (EGEA) also

underlined the importance of extending roadworthiness testing to all road transport vehicles.

On the other hand, various motorcycle users’ groups that submitted contributions to the IIA argued

against the mandatory extension of the scope of the PTI to motorcycles, in line also with the responses

from the campaign. The Federation of European Motorcyclists’ Associations (FEMA) argued that

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the evidence was that the technical state of motorcycles only played a marginal role in accidents

involving motorcycles..

In the

OPC,

among the respondents not linked to the campaign, there was a small majority that

supported extending the scope of the PTI Directive to cover L-category vehicles (53%; 73, 25 ‘no

responses’ or ‘Don’t knows’), whereas again the responses that were part of the campaign

were

against

such an extension to motorcycles.

Figure 7: Survey responses: In your view what would the contribution of this measure be to:

Source: Ricardo et al. (2023), Impact assessment support study, survey results

Figure 8: Survey responses: In your view, to which categories of motorcycle should mandatory PTI be extended?

(multiple responses possible):

Source: Ricardo et al. (2023), Impact assessment support study, survey results

In the

survey,

respondents were asked about different potential measures to extend the scope of the

PTI Directive. For each of the potential measures, around two thirds or more of the respondents

believed that the respective measure would contribute to a high level to delivering Specific Objective

2, i.e. extending the scope to motorcycles (80%; 41, 24 ‘no responses’ or ‘Don’t knows’); agricultural

and forestry tractors (78%; 31, 35 ‘no responses’ or ‘Don’t knows’); and light trailers (66%; 27, 34

‘no responses’ or ‘Don’t knows’). In the

survey

and

interviews,

it was noted that many Member

States already required a PTI for motorcycles, tractors and/or trailers. Some potential challenges of

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this measure were mentioned by the respondents, including the distance that would need to be

travelled to take motorcycles and tractors for an inspection at an inspection centre, and whether a PTI

should be required for tractors that were not used on public roads. In addition, for the lightest trailers

), it was questioned whether a PTI was needed for these, due to the way in which these were used,

and also due to the fact that these trailers are not registered in some countries, such as the Netherlands

and France.

In the responses to the OPC,

SMEs

who had responded were much less supportive extending the

scope of the PTI Directive to motorcycles than large enterprises participating in the OPC, with 38%

(eight) not supporting it, compared to no

large enterprise.

In the response to the survey and

interviews, the fear was expressed that costs for SME inspection companies could increase, if they

had to buy more equipment, or if SME rental companies had to have their vehicles tested more often.

Policy measures: Frequency of PTI tests

The second group of measures considered in the survey and interviews covered measures to increase

the

frequency of testing for certain vehicles.

In the

survey,

more than two thirds of respondents

believed that four of the measures would contribute to a high level to delivering Specific Objective

2, i.e. an annual PTI for N

vehicles (70%; 30, 32 ‘no responses’ or ‘Don’t knows’), an annual PTI

for vehicles over 10 years olds (78%; 39, 25 ‘no responses’ or ‘Don’t knows’), a mandatory PTI for

crashed vehicles with significant damage (70%; 33, 28 ‘no responses’ or ‘Don’t knows’) and for

vehicles with significant modification (67%; 32, 27 ‘no responses’ or ‘Don’t knows’). On the other

hand, a significant majority of respondents (85%; 34, 35 ‘no responses’ or ‘Don’t knows’) believed

that the remaining measure, a simplified PTI for vehicles that had recently passed an RSI, would have

a low contribution to delivering Specific Objective 2.

In the IIA response, CITA called for an increased frequency of PTI for some vehicles. For example,

they supported annual tests for vehicles over 12 years’ old, as the number of these was increasing in

the EU and they would experience more frequent defects as they aged. GOCA Vlaanderen called for

more frequent PTIs for certain vehicles, such as N1 vehicles and vehicles of more than 10 years’ old.

The EGEA also mentioned possibly increasing the frequency of inspections for high mileage

vehicles. The French CNPA and a French inspection company called for the alignment of the

frequency of testing of N1 vehicles, with those of N2 and N3 vehicles, arguing that in France, where

N1 vehicles are tested at the same frequency as cars, they already often had many deficiencies by the

time of their first PTI. The Spanish Association of PTI service providers (AECA-ITV) called for

annual PTIs for all cars, light commercial vehicles and L-category vehicles. The Portuguese ANCIA

also called for an increased frequency of testing for vehicles used for shared mobility or for public

transport services. They also called for a mandatory PTI after a vehicle had been in an accident

affecting its main safety components, which should have the active involvement of insurers, and on

the transfer of ownership of a vehicle. Inspection company Applus also called for a mandatory PTI

after a vehicle had been in an accident (as reported by an insurer), and on the transfer of ownership

of a vehicle. Finally, they recommended that a quality standard for inspection entities and supervisory

bodies be created to improve vehicle inspection and to make this more consistent across the EU.

A common argument in favour of more frequent testing for N1 vehicles, which were mentioned in

different consultation exercises, was that such vehicles were used frequently, and often experienced

a number of technical issues by the time of their first PTI, although other respondents were not

convinced of the added value of this measure. For older vehicles, it was widely suggested that these

deteriorate more quickly than newer vehicles, and so should be tested more frequently. The main

argument against having a simplified PTI for vehicles that had recently passed an RSI was, that it

was not possible to test a vehicle in an RSI in the same way as it was in a PTI -while the potential

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cost of setting up a system to record and exchange this information was noted-, as was the time that

would be needed to amend each PTI to the take account of the recent RSI history of the vehicle. In

relation to requiring a mandatory PTI for crashed vehicles with significant damage and for vehicles

with significant modification, challenges were identified in relation to who makes the respective

judgements and how the information is exchanged. In addition, some respondents considered that a

standard PTI was not sufficient to determine the roadworthiness of some crashed or modified

vehicles.

Policy measures: Mutual recognition of PTI certificates

The third set of measures included two alternative approaches to enable the

recognition of PTI

certificates in other countries,

i.e. other than the one in which the PTI was undertaken. In the

OPC,

a majority of respondents (63%; 97, 11 ‘no responses’ or ‘Don’t knows’) agreed with the proposal

that measures were needed

to enable a vehicle owner to obtain a valid roadworthiness certificate, to

be accepted throughout the EU, in a Member State other than the Member State of registration of the

vehicle.

In the

survey,

respondents were split on the extent of the contribution of each of the two

measures to Specific Objective 3. A marginal majority (51%; 19, 38 ‘no responses’ or ‘Don’t knows’)

felt that requiring the mutual recognition of PTI certificates under certain conditions would have a

high contribution to Specific Objective 3, whereas a minority (38%; 12, 43 ‘no responses’ or ‘Don’t

knows’) felt that way about mutual recognition under bilateral agreements.

In responses to the variation consultation exercises, users and those not directly involved in

inspections tended to be more in favour of the mutual recognition of PTI certificates under certain

conditions, although some recognised that the mutual recognition under bilateral agreements would

be a good first step. However, those more actively involved with inspections were concerned that the

extent of the variation between the approach taken to PTIs in different Member States meant that

mutual recognition would be difficult and potentially lead to adverse effects on safety, unless mutual

recognition was the subject of a bilateral agreement. Linked to this, concerns were also raised that

mutual recognition without the increased harmonisation of PTIs would lead to “PTI tourism”, where

drivers had their vehicles tested in countries where it was easier to pass a PTI.

Policy measures: Electronic roadworthiness certificates

The fourth set of measures consisted of a single measure, i.e.

require that the roadworthiness

certificate is issued in an electronic format.

In their responses to the

survey,

the overwhelming

majority of respondents (94%; 49, 23 ‘no responses’ or ‘Don’t knows’) believed that this measure

would have a high contribution to addressing Specific Objective 3, with a majority of these (63%;

33) believing that a paper version should still be available on request. In their responses to the

survey

and

interview,

various respondents underlined their support for this measure, and for the increased

digitalisation of all aspects of the roadworthiness testing process more generally, due to its potential

benefits for efficiency, the environment (less paper use), enforcement and in potentially opening the

door for new services. The importance of retaining the option to have a paper copy of the certificate

was underlined, so as not to exclude owners who were less digitally literate. The importance of having

a standardised format for the electronic roadworthiness certificate was also a common remark of the

respondents. A potential challenge of such digitalisation was identified for

SMEs

that undertake PTIs

in some countries, if they were not yet digitally connected to the agency that oversaw inspections.

Policy measures: Content of PTI tests

The fifth group covered measures to

improve the current PTI test requirements and procedures.

their responses to the OPC, a small majority (60%; 91, 13 ‘no responses’ or ‘Don’t knows’) was in

favour of

measures to specifically tackle noise-related tampering / non-compliance problems in

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vehicles inspected at the roadside.

SMEs responding to the OPC

were

less supportive

of this

measure, with 29% (six) not supporting it, compared to no

large enterprise

among the responding

large enterprises.

In the

survey,

around two thirds or more of respondents believed that the measures would contribute

to delivering the respective Specific Objectives to a high level, with one exception. The measure that

the vast majority (91%; 50, 20 ‘no responses’ or ‘Don’t knows’) thought would contribute at a high

level to achieving Specific Objective 1 was to require the training of PTI inspectors to inspect electric

vehicles. Around two thirds thought that advanced noise testing for motorcycles (65%; 28, 32 ‘no

responses’ or ‘Don’t knows’) and more advanced testing of braking for HDVs (69%; 27, 36 ‘no

responses’ or ‘Don’t knows’) would contribute to Specific Objective 2 at a high level. The response

was more ambivalent with respect to the contribution of advanced testing of advanced headlamps, as

only a slight majority (52%; 23, 31 ‘no responses’ or ‘Don’t knows’) thought that this would make a

contribution to addressing Specific Objective 2, although a majority (79%; 37, 28 ‘no responses’ or

‘Don’t knows’) thought that this measure would address Specific Objective 1 at a high level.

More detailed responses in both the

survey

and

interviews

regarding the advanced noise testing for

motorcycles ranged from that this was already done in a number of countries, such as Spain, to a

concern that such tests would not be effective, as users could remove any tampered devices before

the PTI. The latter responses came from national authorities, inspecting companies and user groups,

although some felt that such adaptation prior to the PTI was still an additional burden for users. With

respect to the advanced testing of advanced headlamps, some, such as the FIA, were not yet clear of

the scale of the problem, whereas others, such as CITA, argued that such testing was not yet possible.

On the other hand, in some countries it was considered that such tests were already undertaken, e.g.

in Germany and Belgium, using a range of different methods. Some respondents noted that there

could be additional costs for

SMEs

resulting from these measures, if a measure required new

equipment or additional training, particularly in countries with a decentralised testing system, such

as the Netherlands.

The

introduction of new PTI test requirements and procedures

was the subject of the sixth group

of measures. In the responses to the

OPC,

around two thirds of respondents supported similar

measures to those covered in the survey and interviews. For example, 70% (106, 13 ‘no responses’

or ‘Don’t knows’) supported

methods to test the functioning of safety-relevant electronic components,

advanced driver assistance systems (ADAS) and automated functions

being included in the revision

of the PTI Directive, with 66% (100, 12 ‘no responses’ or ‘Don’t knows’) supporting the inclusion

new methods to test vehicles with alternative powertrain technologies (hybrid, full-electric,

hydrogen)

and 64% (96, 13 ‘no responses’ or ‘Don’t knows’)

new methods for measuring exhaust

emissions, for example particle number (PN) and nitrogen oxides (NO

Many responses to the

IIA

also called for similar measures.

In the responses to the

survey,

at least 80% of respondents thought that the respective measures

would address the specified Specific Objectives, e.g. 92% (46, 25 ‘no responses’ or ‘Don’t knows’)

believed that updating the PTI to cover the safety systems introduced by the General Safety

Regulation (GSR) would address Specific Objective 1 to a high level and 88% (45, 24 ‘no responses’

or ‘Don’t knows’) felt the same way about adapting the PTI to the particularities of EVs and hybrids.

Similar proportions, 81% (43, 22 ‘no responses’ or ‘Don’t knows’) for mandatory PN counting and

82% for requiring NO

testing according to the JRC methodology, thought that these measures would

address both Specific Objective 1 and Specific Objective 2 to a high level. In the open responses to

the

survey

and the

interviews,

there was some concern regarding the feasibility of applying NO

testing according to the JRC methodology in northern Member States, particularly the requirement

that testing be undertaken when the vehicle has a warm engine. Again, there were some concerns

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about the impact of any additional costs from these measures on

SMEs

that undertake inspections,

particularly where the PTI system was decentralised.

Policy measures: Scope of RSI Directive

The seventh set of measures focused on

extending the scope of RSIs.

In the responses to the

OPC,

there was a high level of support for

mandatory checks during roadside inspections of commercial

vehicles to ensure the safe securing of cargo

(70%; 99, 22 ‘no responses’ or ‘Don’t knows’).

However, there was only a marginal majority in favour of

extending the rules to other vehicles, (e.g.,

light commercial vehicles, and passenger vehicles, including cars, powered two- and three-wheelers

, M

and L-category vehicles)

(51%; 77, 14 ‘no responses’ or ‘Don’t knows’). In particular,

respondents who were

SMEs

were much

less supportive

of this measure, with 38% (eight) not

supporting it, compared to no

large enterprise

participating in the OPC.

In the

survey,

between two-thirds and three-quarters of respondents believed that the respective

measures would address the associated Specific Objectives at a high level, although in all cases at

least half of the respondents to the survey did not express a view. On one hand, two-thirds of

respondents (67%; 20, 45 ‘no responses’ or ‘Don’t knows’) believed that the introduction of

mandatory standards in relation to cargo securing inspections would address Specific Objective 1 at

a high level. On the other hand, around three quarters of respondents believed that the extension of

the scope of the RSI Directive to N

and L-category vehicles would address Specific Objective 2 at

a high level (76%; 28, 38 ‘no responses’ or ‘Don’t knows’; and 74%; 23, 44 ‘no responses’ or ‘Don’t

knows’, respectively). In their responses to the

survey

and

interview,

various respondents noted that

some of these measures were already undertaken in their respective countries, although a minority of

respondents were not convinced of the added value of each of these measures. In relation to

introducing RSI for N

vehicles, it was suggested that this could bring additional costs, in terms of

lost time, for

SMEs

operating such vehicles.

Policy measures: Content of RSIs

The

introduction of new RSI test methods and procedures

was the subject of the eighth group of

measures. In the responses to the

OPC,

a small majority supported consideration of relevant

measures, as 60% (91, 13 ‘no responses’ or ‘Don’t knows’) supported

measures to specifically tackle

noise-related tampering / noncompliance problems in vehicles inspected at the roadside

and 53%

(78, 17 ‘no responses’ or ‘Don’t knows’) supported

extended emission testing (e.g., NO

and PN),

including the use of remote sensing equipment.

SMEs

participating in the OPC were much

less

supportive

of either of these measures (29% (six) and 40% (eight), respectively), compared to no

respondent large enterprise in both cases.

In the responses to the

survey,

a majority of respondents, who expressed a view, thought that each

of the proposed measures would contribute to addressing both Specific Objective 1 and Specific

Objective 2 at a high level, although more than half of respondents did not have a view on any of

these measures. For example, 81% (26, 43 ‘no responses’ or ‘Don’t knows’) believed that

PN testing

for commercial vehicles

would address Specific Objective 2 at a high level, as did 77% (24, 44 ‘no

responses’ or ‘Don’t knows’) for

and noise testing for all vehicles using remote sensing.

The

measure that the fewest respondents believed would address Specific Objective 2 at a high level was

plume chasing for commercial vehicles

(61%; 14, 52 ‘no responses’ or ‘Don’t knows’). The responses

relating to Specific Objective 1 were similar for each measure. In the responses to the open questions

in the

survey

and

interviews,

various respondents from national authorities were not convinced of

the added value of requiring PN counting during an RSI, if this was also measured in the course of a

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PTI. It was also suggested that remote sensing would only be able to identify vehicles that exceed the

respective emission standards significantly, rather than being able to identify slight exceedances.

In the IIA response in relation to the RSI Directive, CITA called for cargo securing requirements for

cargo vehicles to be set in type-approval, in order to facilitate the inspection of the security of cargo

in RSIs. Ireland’s RSA called for some changes to improve the RSI Directive, including more

specific wording around failures involving frontal protection systems and tampered emission control

systems. They also suggested that consideration could be given to expanding the scope of the RSI

Directive. The inspection company Applus suggested that the RSI Directive should be extended to

all vehicles that were able to circulate on roads in the EU to check their emission levels, noise levels,

overloading and other relevant technical issues. They also suggested that remote sensing could be

used to identify the need for additional inspections for high polluting vehicles. The Nordic Logistics

Association highlighted the importance of electronic data exchange and the storage of the results of

RSIs, and for RSI authorities to have access to this information, in order to prevent drivers being

subject to another RSI when they cross a border. They also underlined the importance of digital tools,

including those that could support the registration of vehicles, in making it easier to inspect vehicles,

and so make this more efficient, thus saving time for inspectors and for those being inspected.

Policy measures: Testing software in PTIs and RSIs

The ninth set of measures included a single measure relating to both the PTI and RSI Directives:

require the testing of software status/integrity of safety and/or emission relevant systems in the PTI

for all vehicles and as part of technical roadside inspections of commercial vehicles.

The

OPC

included a question on a similar measure, but only in relation to PTI, which was supported by two

thirds of respondents (65%; 100, nine ‘no responses’ or ‘Don’t knows’). The importance of checking

a vehicle’s software, at least during PTIs, was highlighted by a number of inspection bodies in the

IIA.

In the

survey,

a high proportion of respondents believed that the measure would address both

Specific Objective 1 (86%; 42, 26 ‘no responses’ or ‘Don’t knows’) and Specific Objective 2 (81%;

38, 28 ‘no responses’ or ‘Don’t knows’) at a high level. In the open responses to the

survey

and

interviews,

some authorities were concerned about the additional costs of this measure, particularly

SMEs.

On the other hand, those that undertook inspections believed that the test could be

relatively straightforward, even automated, as long as those undertaking inspections had easy access

to the relevant information within the vehicle and also to relevant manufacturer databases that

contained the necessary information on the software used.

Policy measures: Access and exchange of information/data

The tenth set of measures focused on

access and exchange of information/data

that was needed to

support PTIs and RSIs.

In the response to IIA, CITA called for all those undertaking inspections to have access to vehicle-

specific original data in a non-discriminatory, free and independent manner, given that technical

inspections are undertaken for the authorities of the Member States, They also underlined the

importance of relevant stakeholders being able to verify that the right version of approved software

was being used by the vehicle. Germany’s Central Agency for PTI, the FSD, also underlined the

importance of access to in-vehicle data and diagnostic information in an independent and reliable

way, specifically the information made available in the context of EU type-approval legislation, along

with unrestricted access to the vehicle data and software, covering the whole lifetime of the vehicle.

Similarly, the Spanish AECA-ITV underlined the importance of PTI inspection providers having

access to the original vehicle data, including up-to-date software, in a non-discriminatory, free and

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independent manner, so that vehicles could be appropriately tested. The Portuguese ANCIA also

underlined the importance of testing services having access to the technical specifications of a

vehicle’s safety systems to be able to properly test these, and to be able to check that a vehicle’s

software was approved and up to date. Austrian VFT and BdF, and the German DKZ also underlined

that, in order to facilitate the inspection of the functionality of safety systems, testing centres should

have easy access to the relevant OBD data, free of charge. They also noted that the implementation

of Regulation (EU) 2019/621 regarding ePTI had been more difficult than expected and so more

detailed provisions should be included in the revised RWP. GOCA Vlaanderen also emphasised the

importance of free access to specific PTI-related data for each individual vehicle in order to be able

to properly inspect modern vehicles. Similarly, Ireland’s RSA called for manufacturers to be required

to provide to Member States with “accessible and standardised” information relating to the test items,

at no cost to Member States, and to provide sufficient access to in-vehicle data in PTIs to enable the

necessary inspections. They also argued that testing inspection companies should have similar access

to these information and data. Inspection company Applus argued that organisations involved in

statutory activities, such as vehicle inspections, should have a “clear and unfiltered access” to vehicle

data, potentially via a central hub. They also called for the information needed for an inspection to

be made available in a standardised format in an easy-to-access, computer-readable format on the

European level, to facilitate access to the OBD, for example. Applus also underlined the importance

of inspections being able to check that the appropriate, non-modified software was present on the

vehicle. The EGEA underlined the importance of direct access to in-vehicle data to facilitate the

testing of safety and environmental control systems, and also called for all inspection equipment to

have digital network capability to enable the secure transmission of data between inspection sites and

the respective authorities. GTÜ, the German association of independent PTI inspectors, also

underlined the importance of being able to access vehicle data using standardised interfaces, and of

having internet access at all inspection sites. They also noted that they would welcome a system that

would allow Member States to issue inspection reports solely in a digital format. The FIA also

underlined that the relevant diagnostic data and functions must be made “conveniently accessible”

for inspection bodies free of charge, as these were undertaking a government activity, with the

explicit consent of users. They also called for the implementation of an independent, vehicle security

certification scheme to allow “efficient and effective” verification during testing to ensure that the

most up-to-date security, safety and environmental protection updates have been installed. The

ÖAMTC’s response made similar points.

In the

OPC,

questions were asked about relevant measures relating to both PTIs and RSIs. Two-

thirds of respondents (67%; 102, 11 ‘no responses’ or ‘Don’t knows’) supported

extending (or

clarifying) existing rules on access to in-vehicle data…, with data protection safeguards

for PTIs,

whereas a slightly smaller proportion (62%; 93, 15 ‘no responses’ or ‘Don’t knows’) supported this

for RSIs. In both cases,

vehicle and equipment manufacturers/suppliers,

who participated in the

OPC, were less supportive of this provision than other respondents, e.g. for PTI (58%; seven, three

‘no responses’ or ‘Don’t knows’) and for RSI (50%; six, three ‘no responses’ or ‘Don’t knows’). In

addition, 59% (92, nine ‘no responses’ or ‘Don’t knows’) supported

new methods for reading out

onboard data stored in the vehicles

for PTIs, although again

vehicle and equipment

manufacturers/suppliers,

who participated in the OPC, were less supportive of this measure (38%;

five, two ‘no responses’ or ‘Don’t knows’) than other respondents. In addition, nearly two thirds of

OPC respondents (64%; 96, 14 ‘no responses’ or ‘Don’t knows’) were supportive of

granting

roadside inspection authorities access to electronic data,

which again was less supported by

vehicle

and equipment manufacturers/suppliers,

who participated in the OPC, than other respondents (31%;

four, two ‘no responses’ or ‘Don’t knows’).

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In the

survey,

a majority of respondents believed that

further defining data governance procedures

and the means of access to vehicle technical information by testing centres free of charge and in

standardised format

would address both Specific Objective 1 (87%; 45, 23 ‘no responses’ or ‘Don’t

knows’) and Specific Objective 3 (75%; 38, 24 ‘no responses’ or ‘Don’t knows’) to a high level. A

similarly high proportion believed that

enabling and use of independent remote access to in-vehicle

data in the RSIs of commercial vehicles

would address both Specific Objective 1 (81%; 34, 33 ‘no

responses’ or ‘Don’t knows’) and Specific Objective 2 (73%; 30, 34 ‘no responses’ or ‘Don’t knows’)

to a high level. Around three-quarters of respondents (75%; 24, 43 ‘no responses’ or ‘Don’t knows’)

believed that

requiring the electronic storage of RSI reports in national databases, as well as the

access and exchange of RSI-relevant data to RSI authorities in other EU Member States through a

common IT system

would address Specific Objective 3 at a high level. In response to the open

survey

and

interview

questions, various respondents underlined that

enabling and use of independent remote

access to in-vehicle data

was as important for PTIs as it was for RSIs, and so underlined that this

measure should also be considered in the context of PTIs. In this context, EReg underlined that they

supported the three measures in this section applying to all three Directives that are part of the RWP.

Various respondents, including CITA, EGEA and EReg, underlined the importance of free and easy

access to in-vehicle data to enable the proper inspection of vehicles. Many respondents also

underlined the importance of storing relevant data in a structured format, rather than storing the full

RSI report. A couple of respondents suggested that

SMEs

would benefit from having easier access

to information.

Policy measures: Measures relating to vehicle registration

The final – eleventh – set of measures focused on

potential amendments to the Vehicle Registration

Documents Directive.

In the IIA response in relation to vehicle registration, CITA called for a standardised exchange of

data between type-approval and licencing authorities, to eliminate the need to carry the registration

certificate in the vehicle (or even its replacement entirely with an electronic version) and the

possibility for relevant authorities and bodies to access vehicle registration data, no matter which

Member State the vehicle was registered in. Spanish AECA-ITV called for the establishment of an

electronic platform in which Member States were able to access the registration documents and

certificates of conformity of all vehicles. The Nordic Logistics Association agreed with the

difficulties in enforcing road safety measures in cross-border traffic and trade in the EU, and

underlined its belief that sharing vehicle registration data, and other safety-relevant information, of

vehicles between Member States was important to address this problem.

In the

OPC,

respondents were asked whether they supported four relevant measures, each of which

was supported by around three-quarters of respondents, with the most popular being

adding data on

major accidents of a vehicle to the vehicle register

(76%; 115, 13 ‘no responses’ or ‘Don’t knows’).

This was followed by

improved exchange of roadworthiness data between Member States in

electronic format

(75%; 116, 10 ‘no responses’ or ‘Don’t knows’),

full digitalisation of registration

documents

(74%; 110, 16 ‘no responses’ or ‘Don’t knows’) and

adding odometer data to the vehicle

(72%; 111, nine ‘no responses’ or ‘Don’t knows’). Responses to the

IIA

also supported the

sharing of relevant information between Member States.

In the

survey,

a large majority of respondents that had a view (at least 85% in all cases) believed that

the respective measures would have a high impact on the respective Specific Objectives. Over 90%

of respondents believed that

providing electronic access to relevant data to the registration

authorities of other EU Member States through the use of a common IT system

(95%; 38, 35 ‘no

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responses’ or ‘Don’t knows’) and

adding a minimum set of new data to the vehicle register

(93%;

42, 30 ‘no responses’ or ‘Don’t knows’) would address Specific Objective 3 to a high level. Slightly

fewer respondents believed that

introducing the requirement that any vehicle transformation has to

be approved and registered

and

increasing the harmonisation of the technical data in the vehicle

registration documents on the basis of a common standard

would address Specific Objective 3 at a

high level (91%; 30, 42 ‘no responses’ or ‘Don’t knows’; and 88%; 28, 43 ‘no responses’ or ‘Don’t

knows’, respectively). The proportion believing that

requiring issuing of the registration certificates

(Annex I) in digital format

and that

requiring that Member States update vehicle registration data on

a regular basis

would address Specific Objective 3 at a high level was marginally lower (85%; 23,

48 ‘no responses’ or ‘Don’t knows’; and 86%; 25, 46 ‘no responses’ or ‘Don’t knows’, respectively).

In the responses to open questions in the

survey

and

interviews,

many national authority respondents

highlighted that 17 Member States already used Eucaris for the purpose of data exchange, and that

this system worked well. Many of the same organisations underlined that data on the vehicle register

should be harmonised and available to all organisations that were involved in undertaking PTIs and

RSIs for national authorities, while EReg and some if its members called for a larger set of data to be

included in the vehicle register. EReg also generally supported the digitalisation of the vehicle

registration documents and the mutual recognition of these. Various national authorities, and users,

underlined the importance of the data in the vehicle register being updated as soon as relevant changes

happen. It was suggested that additional costs could arise for

SMEs

that were not currently digitally

connected in order to be able to access electronic documentation and information, although it was

also suggested that SMEs would have a lot to gain by having better access to relevant standardised

information.

3.5. Feedback received on policy options

Various industry respondents, including PTI operators, called for the extension of the PTI Directive

to cover all road vehicles. PO3 and PO1b introduce the obligation to inspect motorcycles at PTI,

albeit at a various level of stringency and with PO3 being more ambitious, while PO2 and PO1a allow

to substitute PTI with RSI. While stakeholders belonging to motorcyclists’ groups at EU or national

level did not support such extension in the OPC, in the survey most of the respondents supported

mandatory PTI for motorcycles with the objective to reduce tampering and the detection of defected

vehicles. Stakeholders also noted that many Member States already required a PTI for motorcycles,

as well as for tractors and/or trailers. In the consultations, SMEs were much more likely not to support

extending the scope of the PTI Directive to motorcycles than large enterprises, arguing that costs for

SME inspection companies could increase, if they had to buy more equipment.

All policy options include mandatory testing after significant modification of a vehicle, which was

supported by stakeholders in the survey. Regarding the increased frequency of testing, PO1b and

PO2 introduce annual emission testing for vans and a requirement for an annual PTI for vehicles over

10 years old, all these measures being supported by a majority of stakeholders in the survey.

The recognition of PTIs conducted in another Member State was an issue that the majority of

stakeholders responding to the OPC considered as necessary to address. PO3 introduces a full

recognition, while PO1b and PO2 require the recognition of the PTI from another MS than the MS

of registration for a period of up to 6 months. PO1a on the other hand envisages only a recognition

based on bilateral agreements. Stakeholder views on this differ to quite some extent: vehicle owners

and those not directly involved in PTI inspections tended to be more in favour of the mutual

recognition of PTI certificates under certain conditions, although some recognised that the mutual

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recognition under bilateral agreements would be a good first step. Those more actively involved with

inspections were concerned that the difference between the approach taken to PTIs in different

Member States meant that mutual recognition would be difficult and potentially lead to adverse

effects on safety. Concerns were also raised that mutual recognition without the increased