Closed

Testing safe lightweight vehicles and improved safe human-technology interaction in the future traffic system

HORIZON Research and Innovation Actions

Basic Information

Identifier: HORIZON-CL5-2021-D6-01-10
Programme: Safe, Resilient Transport and Smart Mobility services for passengers and goods
Programme Period: 2021 - 2027
Status: Closed (31094503)
Opening Date: June 24, 2021
Deadline: October 19, 2021
Deadline Model: single-stage
Budget: €12,000,000
Keywords: Artificial IntelligenceDigital AgendaVehicle engineeringAutomotiveSocial InnovationTransport engineeringhuman machine interaction, vehicle safety

Description

ExpectedOutcome:

Project results are expected to contribute to the following expected outcomes:

For Area A:

Safer but also lighter and circular vehicle structures.
Advanced vehicle concepts with higher compatibility between vehicles of different sizes and masses in dissimilar crashes.
Advanced structural designs tolerant to a wider set of crash angles.
Demonstration of a minimum number of crash tests designed to validate virtual testing for a large number of different scenarios
Improved safety in future mixed traffic scenarios including an increasing number of automated vehicles

For Area B

Reduced driver distraction as an important factor in road crashes.
Intuitive and unobtrusive information of drivers and other road users about expected actions at any time.
Safer mobility for all road users including the ones with impaired mental and/or physical capacity.
Availability of human-centric adaptive interfaces and positive stimulation and utilisation of human abilities by new human-technology interfaces.
Improved validation methods for HMI.

Scope:

Actions should address the activities EITHER under area A) Testing safe lightweight vehicles OR under area B) Safe human-technology interaction in the future traffic system. Proposals should clearly indicate which area they are covering.

Area A –Testing safe lightweight vehicles

Automotive safety has significantly progressed in the last decades thanks to advanced modelling and testing capabilities and new structural concepts, as well as the introduction of active safety.

Future vehicles and their structures, however, will have to be lighter and lighter, and this means already an intrinsic reduction of safety when crashing with a heavier crash counterpart. Moreover, new structural concepts will need to be more and more designed with a circular use of materials in mind, and structures with mixed light materials and related manufacturing concepts (including casting and 3D printing of complex shapes, for instance in energy absorbers or highly integrated structural components) will be widely different from today’s mostly sheet steel based concepts. Advanced testing on crash, toughness, fracture and fatigue of new materials and concepts should be performed where relevant. A smart integration of these concepts are expected to lead the demonstration of a more sustainable and safe body-in-white with at least a 10% weight reduction on already achieved results for multimaterial research structures.

In this context, the proposed actions should analyse the crash scenarios of the future, considering active safety devices but also their potential failure and the fact that for a long time there will be a mixed traffic situation where automated and semi-automated vehicles will share the road with normal “manually driven” vehicles and all types of unprotected road users.

This requires a new way of conceiving structures and their components, to ensure that all requirements are met at the same time and to further increase safety by including vehicle compatibility concept, like harmonised rigidity between light and heavy vehicles, so that the heavy vehicle helps the more vulnerable one in absorbing the impact energy. Standardised positions for crash absorbing elements should be addressed to ensure the best engagement scenarios, as well as multi-angle optimisation, to avoid that structures are optimised only for the exact test cases in regulation or in EuroNCAP tests. A significant number of crash tests is expected to be performed for validating the different scenarios.

Area B –Safe human-technology interaction in the future traffic system

Another challenge for the safety in future transport systems and services is the ever growing and intensified human interaction with ubiquitous digital content. The overload of various kinds of information from multiple sources can lead to increased driver or unprotected road user distraction and have negative impacts on road safety.

Human machine interfaces (HMI) with adaptive characteristics continue to be developed and new functionalities are continuously added, yet the impacts of those systems on the behaviour of drivers and other road users are not sufficiently known. Further research on the effects of such technologies in road transport safety is required.

These adaptive HMI systems can support a wide range of traffic users and could be included in scenarios based on the mixed traffic and accidentology where needed. As such the applications are not limited to higher levels of vehicle automation. Therefore, they need to consider a wide variation of human capabilities and reactions as well as long-term mental and physical capacities (including disabilities and disorders) and instantaneous limitations in capabilities (collapse, illness, drowsiness, etc.).

In particular, the following aspects should be considered by future research:

Design and development of intuitive, understandable, non-distracting and reliable adaptive interfaces for human-technology interaction in road vehicles minimising training needs for safe usage.
Develop concepts of external interfaces, also considering the characteristics (for instance speed, direction) that are possible to interpret and understand by all road users.
Understand long-term effects (physical and mental), potential risks and possible benefits for road users exposed to and actively using adaptive HMI technologies, and propose means to improve or maintain road user performance in terms of safety.
Development of safety validation methods for new adaptive HMI technologies.

While this topic is open to research on all human-technology interaction in the road transport system, specific issues of the interaction of highly automated vehicles with their occupants and other road users are covered in topic HORIZON-CL5-2022-D6-01-02.

Typically, projects should have a duration of 36 to 48 months. Nonetheless, this does not preclude submission and selection of proposals requesting other amounts or durations.

Social innovation is recommended when the solution is at the socio-technical interface and requires social change, new social practices, social ownership or market uptake.

Specific Topic Conditions:

Activities are expected to achieve TRL 5-6 by the end of the project – see General Annex B.

Cross-cutting Priorities:

Social Innovation

View on EU Portal →

Destination & Scope

This Destination includes activities addressing safe and smart mobility services for passengers and goods.

Europe needs to manage the transformation of supply-based transport into safe, resilient and sustainable transport and demand-driven, smart mobility services for passengers and goods. Suitable research and innovation will enable significant safety, environmental, economic and social benefits by reducing accidents caused by human error, decreasing traffic congestion, reducing energy consumption and emissions of vehicles, increasing efficiency and productivity of freight transport operations. To succeed in this transformation, Europe’s ageing (and not always sustainable) transport infrastructure needs to be prepared for enabling cleaner and smarter operations.

Europe needs also to maintain a high-level of transport safety for its citizens. Resilience should be built in the transport systems to prevent, mitigate and recover from disruptions. Research and innovation will underpin the three safety pillars: technologies, regulations and human factors.

This Destination contributes to the following Strategic Plan’s Key Strategic Orientations (KSO):

C: Making Europe the first digitally enabled circular, climate-neutral and sustainable economy through the transformation of its mobility, energy, construction and production systems;
A: Promoting an open strategic autonomy[[‘Open strategic autonomy’ refers to the term ‘strategic autonomy while preserving an open economy’, as reflected in the conclusions of the European Council 1 – 2 October 2020.]] by leading the development of key digital, enabling and emerging technologies, sectors and value chains to accelerate and steer the digital and green transitions through human-centred technologies and innovations.

It covers the following impact areas:

Industrial leadership in key and emerging technologies that work for people;
Smart and sustainable transport.

The expected impact, in line with the Strategic Plan, is to contribute to “Safe, seamless, smart, inclusive, resilient and sustainable mobility systems for people and goods thanks to user-centric technologies and services including digital technologies and advanced satellite navigation services”, notably through:

Accelerating the implementation of innovative connected, cooperative and automated mobility (CCAM) technologies and systems for passengers and goods (more detailed information below).
Further developing a multimodal transport system through sustainable and smart long-haul and urban freight transport and logistics, upgraded and resilient physical and digital infrastructures for smarter vehicles and operations, for optimised system-wide network efficiency (more detailed information below).
Drastically decreasing the number of transport accidents, incidents and fatalities towards the EU’s long-term goal of moving close to zero fatalities and serious injuries by 2050 even in road transportation (Vision Zero) and increase the resilience of transport systems (more detailed information below).

Connected, Cooperative and Automated Mobility (CCAM)

The aim of relevant topics under this Destination is to accelerate the implementation of innovative connected, cooperative and automated mobility (CCAM) technologies and systems. Actions will help to develop new mobility concepts for passengers and goods – enabled by CCAM - leading to healthier, safer, more accessible, sustainable, cost-effective and demand-responsive transport everywhere. CCAM solutions will shift design and development from a driver-centred to mobility-user oriented approach, providing viable alternatives for private vehicle ownership while increasing inclusiveness of mobility. CCAM must be integrated in the whole transport system to fully exploit the potential benefits of CCAM and minimise potential adverse effects, such as increasingly congested traffic or new risks in mixed traffic environments.

The focus is on road transport, but relevant interfaces with other modes (for instance transfers and integration with public transport or rail freight transport) will be considered.

All technologies, solutions, testing and demonstration activities resulting from these actions should be documented fully and transparently, to ensure replicability, increase adoption, up-scaling, assist future planning decisions and EU and national policy-making and increase citizen buy-in.

Actions are in line with the recommendations of the new European Partnership on CCAM. The Vision of the Partnership is: “European leadership in safe and sustainable road transport through automation”. It aims to harmonise European R&I efforts to accelerate the implementation of innovative CCAM technologies and services. It aims to exploit the full systemic benefits of new mobility solutions enabled by CCAM. The European Partnership on CCAM plans to closely cooperate with other European Partnerships, in particular with “Towards zero emission road transport” (2ZERO), “Driving Urban Transitions” (DUT), “Key digital technologies” (KDT), “Smart networks and services” (SNS) and “AI, data and robotics” (AI). The European Partnership will establish cooperation mechanisms to ensure close interaction when defining R&I actions to maximise synergies and avoid overlaps.

R&I actions taking place at a socio-technical level aiming to better understand the science-society relationship (particularly when social practices, market uptake or ownership are concerned) should favour solutions that are grounded in social innovation in order to achieve its desired outcomes, i.e. by matching innovative ideas with social needs and by forming new collaborations between public and private actors, including civil society and researchers from the Social Sciences and Humanities (SSH).

To test CCAM solutions, applicants can seek possibilities of involving the European Commission’s Joint Research Centre (JRC) in order to valorise the relevant expertise and physical facilities of JRC in demonstrating and testing energy and mobility applications of the JRC Living Lab for Future Urban Ecosystems https://ec.europa.eu/jrc/en/research-facility/living-labs-at-the-jrc

The main impacts to be generated by topics targeting connected, cooperative and automated mobility under this Destination are:

Validated safety and security, improved robustness and resilience of CCAM technologies and systems.
Secure and trustworthy interaction between road users, CCAM and “conventional” vehicles, infrastructure and services to achieve safer and more efficient transport flows (people and goods) and better use of infrastructure capacity.
Seamless, affordable and user oriented CCAM based mobility and goods deliveries for all and high public acceptance of these services with clear understanding of its benefits and limits as well as rebound effects; based on the changing mobility needs and desires of a society in transition (digitally and environmentally).
Better coordination of R&I and large-scale testing activities in Europe and expanded knowledge base on CCAM solutions.
European leadership in the development and deployment of connected and automated mobility and logistics services and systems, ensuring long-term growth and jobs.

Multimodal and sustainable transport systems for passengers and goods

Multimodal and sustainable transport systems are the backbone for efficient mobility of passengers and freight. In particular, the areas of infrastructure, logistics and network/traffic management play a major role in making mobility and transport climate neutral, also through the digitalisation of the sectors. At the same time, being vulnerable to climate change and other disruptions, resilience in these three areas need to be increased. New and advanced infrastructures across all transport modes are required to enable the introduction of new vehicles, operations and mobility services. Furthermore, efficient and smart multimodal logistics are key for seamless and sustainable long-haul, regional and urban freight transport movements. Finally, dynamic multimodal network and traffic management systems are the “glue” of the entire transport network, for optimised door-to-door mobility of both passengers and freight.

To test solutions related to multimodal and sustainable transport systems for passengers and good, applicants may seek possibilities of involving the European Commission’s Joint Research Centre (JRC) in order to valorise the relevant expertise and physical facilities of JRC in demonstrating and testing energy and mobility applications of the JRC Living Lab for Future Urban Ecosystems[[https://ec.europa.eu/jrc/en/research-facility/living-labs-at-the-jrc]].

The main impacts to be generated by topics targeting Multimodal and sustainable transport systems for passengers and goods under this Destination are:

Upgraded and resilient physical and digital infrastructure for clean, accessible, affordable, connected and automated multimodal mobility.
Sustainable and smart long-haul, regional and urban freight transport and logistics, through increased efficiency, improved interconnectivity and smart enforcement.
Reduced external costs (e.g. congestion, traffic jams, emissions, air and noise pollution, road collisions) of urban, peri-urban (regional) and long distance freight transport as well as optimised system-wide network efficiency and resilience.
Enhanced local and/or regional capacity for governance and innovation in urban mobility and logistics.

Safety and resilience - per mode and across all transport modes

Safety and resilience are of primary concern for any transport system. The EU set ambitious targets in its 2011 Transport White Paper, the third Mobility Package and, more recently, the Sustainable and Smart Mobility Strategy[[COM(2020) 789 final.]]. COVID-19 has been a stark reminder of the importance of resilience to external disruptions, particularly for transport. Research and innovation will underpin the three pillars affecting safety and resilience: technologies; regulations (alongside acceptable level of risks); and human factors (individual and organisational aspects, including interaction with automation). The approach is risk-based and systemic, including transport means/vehicles, infrastructure, the physical environment (e.g. weather) and the various actors (e.g. manufacturers, regulators, operators, users) as well as all their interfaces, including certification and standardisation bodies.

Synergies should be exploited across research at national, EU and international level together with national authorities, EU agencies and international organisations to improve rulemaking, safety promotion and oversight.

The main impacts to be generated by topics targeting transport safety and resilience under this Destination are:

Safety in Urban Areas/ Road Transport Safety

50% reduction in serious injuries and fatalities in road crashes by 2030.
Improved reliability and performance of systems that aim to anticipate and minimize safety risks, avoiding risks and collisions, and reducing the consequences of unavoidable crashes.
Drastic reduction of road fatalities and serious crash injuries in low and medium income countries in Africa.
Better design principles of future road transport systems enabling also better traffic flow in big cities.

Waterborne Safety and Resilience

Ensure healthy passenger shipping by preventing and mitigating the spread of contagious diseases and infections.

Aviation Safety and Resilience

Decrease number of accidents and incidents due to organisational/human/automation factors and external hazards in all phases of flight, also beyond CAT category (80% goal in FlightPath2050), while enabling all weather operations.
Saving lives following a crash (post-crash survivability).
Anticipate emergence of new threats that could generate potential accidents and incidents (short, medium, and long term).
Ensure safety through aviation transformation (from green/digital technologies uptake up to independent certification).
Maintain safety and resilience despite the scale, pace and diversity of new entrants.

Eligibility & Conditions

General conditions

1. Admissibility conditions: described in Annex A and Annex E of the Horizon Europe Work Programme General Annexes

Proposal page limits and layout: described in Part B of the Application Form available in the Submission System

2. Eligible countries: described in Annex B of the Work Programme General Annexes

A number of non-EU/non-Associated Countries that are not automatically eligible for funding have made specific provisions for making funding available for their participants in Horizon Europe projects. See the information in the Horizon Europe Programme Guide.

3. Other eligibility conditions: described in Annex B of the Work Programme General Annexes

4. Financial and operational capacity and exclusion: described in Annex C of the Work Programme General Annexes

5. Evaluation and award:

Award criteria, scoring and thresholds are described in Annex D of the Work Programme General Annexes

Submission and evaluation processes are described in Annex F of the Work Programme General Annexes and the Online Manual

To ensure a balanced portfolio, grants will be awarded to applications not only in order of ranking but at least also to the highest-ranked proposal in each area, i.e. one proposal for area A) Testing safe lightweight vehicles and another one for area B) Safe human-technology interaction in the future traffic system, provided that the applications attain all thresholds.

Indicative timeline for evaluation and grant agreement: described in Annex F of the Work Programme General Annexes

6. Legal and financial set-up of the grants: described in Annex G of the Work Programme General Annexes

Specific conditions

7. Specific conditions: described in the specific topic of the Work Programme.

Documents

Call documents:

Standard application form — call-specific application form is available in the Submission System

Standard application form (HE RIA, IA)

Standard evaluation form — will be used with the necessary adaptations

Standard evaluation form (HE RIA, IA)

MGA

HE General MGA v1.0

Additional documents:

HE Main Work Programme 2021–2022 – 1. General Introduction

HE Main Work Programme 2021–2022 – 8. Climate, Energy and Mobility

HE Main Work Programme 2021–2022 – 13. General Annexes

HE Programme Guide

HE Framework Programme and Rules for Participation Regulation 2021/695

HE Specific Programme Decision 2021/764

EU Financial Regulation

Rules for Legal Entity Validation, LEAR Appointment and Financial Capacity Assessment

EU Grants AGA — Annotated Model Grant Agreement

Funding & Tenders Portal Online Manual

Funding & Tenders Portal Terms and Conditions

Funding & Tenders Portal Privacy Statement

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