WInSiC4AP core objective is to contribute in developing reliable technology bricks for efficient and cost-effective applications addressing social challenges and market segments where Europe is a recognized global leader as well as automotive, avionics, railway and defence. WInSiC4AP approach is to rely on the strength of vertical integration allowing optimization, technologies fitting application requirements, developing the full ecosystem and approach relevant issues as reliability in the full scope. That enhances the competitiveness of EU- Industries as well as TIER1 and TIER2 down to the value chain in a market context where other countries today, such as the USA or Japan, are advancing and new players accessing SiC enter in the market. New topologies and architecture will be developed for targeted application simulating operational environment, at laboratory level, driving the needed and still missed technologies, components and demonstrators to fill the gap between current state of the art and the very high demanding specifications. WInSiC4AP framework has been built so that companies working in different domains (i.e. automotive car maker and TIER1-2 and avionics, railway and defence TIER1-TIER2) and in the vertical value chain (semiconductor suppliers, companies manufacturing inductors and capacitors) as well as academic entities and laboratories will collaborate to co-design solutions, solve problems and exchange know-how, such that unforeseen results may also emerge. WInSiC4AP will be supported with synergy between ECSEL JU and ESI funding enabling complementary activities with relevant economic and social impact envisage in a less development region of Union.

The main objective of the INCLUSION project is to understand, assess and evaluate the accessibility and inclusiveness of transport solutions in European prioritised areas, identify gaps and unmet needs, propose and experiment with a range of innovative and transferable solutions, including ICT-enabled elements, ensuring accessible, inclusive and equitable conditions for all and especially vulnerable user categories. INCLUSION will address a large set of case studies (at least 50) involving different forms of geographical areas and transport contexts, demographic categories, population groups and mobility solutions, providing concrete experiences from various European sites and pilot initiatives involving a variety of regulatory and business frameworks, supporting technologies, organisational and operational conditions. Complementary to this, a number of innovative solutions will be concretely tried out and validated through real-life experiments (Innovation Pilot Labs) in a mix of urban, peri-/sub-urban and rural target areas in Belgium, Germany, Hungary, Italy, Spain and the UK, offering a variety of different transport environments, socio-economic contexts, cultural and geographical conditions. Expected results include: an understanding of the main challenges affecting transport provision and accessibility in the different type of prioritised areas; a structured view highlighting the dependencies among spatial and environmental characteristics, populations segments and their mobility needs; in-depth examination of 10 innovative PT approaches and a wider catalogue of at least 40 promising cases contributing to more accessible, inclusive and equitable transport solutions, complemented by innovative solution components validated in real-life experiments; a set of recommendations and an “option generator” for the development and deployment of mobility solutions addressing the needs of vulnerable user communities in European prioritised areas

Despite technological breakthroughs in connected and automated transport, the total transformation of existing transportation into a fully autonomous system is still decades away. In the meantime, mixed traffic environments with semi-autonomous vehicles proactively passing the dynamic driving task back to the human driver, whenever system limits are approached, is expected to become the norm. Such a Request to Intervene (RtI) can only be successful and met with trust by end-users if the driver state is continuously monitored and his/her availability properly evaluated and sufficiently triggered (through tailored human-machine interfaces - HMIs). In parallel, driver training has to evolve to account for the safe and sensible usage of semi-automated driving, whereas driver intervention performance has to be made an integral part of both driver and technology assessment. Besides, the ethical implications of automated decision-making need to be properly assessed, giving rise to novel risk and liability analysis models. The vision of Trustonomy (a neologism from the combination of trust + autonomy) is to maximise the safety, trust and acceptance of automated vehicles by helping to address the aforementioned technical and non-technical challenges through a well-integrated and inter-disciplinary approach, bringing domain experts and ordinary citizens to work closely together. Trustonomy will investigate, setup, test and comparatively assess, in terms of performance, ethics, acceptability and trust, different relevant technologies and approaches, including driver state monitoring systems, HMI designs, risk models, and driver training methods. This will be done through both simulator and field based studies, in a variety of autonomous driving and RtI scenarios, covering different types of users (in terms of age, gender, driving experience, etc.), road transport modes (private cars, trucks, buses), levels of automation (L3 - L5) and driving conditions.