The design and realization of age-friendly living and working environments is a huge challenge that we have just only started to address as the number of older citizens who are and want to continue being active members of society and live independently is constantly increasing. SmartWork builds a worker-centric AI system for work ability sustainability, integrating unobtrusive sensing and modelling of the worker state with a suite of novel services for context and worker-aware adaptive work support. The unobtrusive and pervasive monitoring of health, behaviour, cognitive and emotional status of the worker enables the functional and cognitive decline risk assessment. The holistic approach for work ability modelling captures the attitudes and abilities of the ageing worker and enables decision support for personalized interventions for maintenance/improvement of the work ability. The evolving work requirements are translated into required abilities and capabilities, and the adaptive work environment supports the older office worker with optimized services for on-the-fly work flexibility coordination, seamless transfer of the work environment between different devices and different environments (home, office, on the move), and on-demand personalized training. The SmartWork services and modules also empower the employer with AI decision support tools for efficient task completion and work team optimization through flexible work practices. Optimization of team formation, driven by the semantic modelling of the work tasks, along with training needs prioritization at team level to identify unmet needs, allow employers to optimize tasks (e.g. needed resources), shifting focus on increased job satisfaction for increased productivity. Formal and informal carers are able to continuously monitor the overall health status and risks of the people they care for, thus providing full support to the older office worker for sustainable, active and healthy ageing.

The EUROBENCH project aims at creating the first benchmarking framework for robotic systems in Europe. The framework will allow companies and researchers to test the performance of robots at any stage of development. The project will primarily focus on bipedal machines, i.e. exoskeletons, prosthetics and humanoids, but will be designed to be easily extended to other robotic domains. The EUROBENCH framework will be composed of: - A methodological component, which will include methods and metrics to calculate the System Ability Levels of a robotic system. These methods will be integrated in a professional software tool to permit its wide use across domains and laboratory conditions. The main goal of this unified software is to facilitate the use of benchmarking methodology at all levels from research to pre-commercial prototyping. - An experimental component, which will concentrate the state-of-the-art test benches in two facilities, one for wearable robots (including exoskeletons and prostheses), and one for humanoid robots. These facilities will allow companies and researchers to perform standardized tests on advanced robotic prototypes in a unique location, saving resources and time, and preparing for certification processes. During the project, the Consortium will provide Financial Support to Third Parties interested in: - Designing and developing specific test benches or benchmarking methods. These solutions will be integrated into the framework, and made available to the industrial and academic community. - Using the framework, at zero-costs, to test the performance of different kinds of robots. This will allow to validate the EUROBENCH outputs and prepare for the exploitation of results. The successful achievement of these goals will put Europe in the lead on providing the groundwork for the evaluation of robotic systems, facilitating the process of bringing innovative robotic technologies forward to market.

Increasing demand from the growing and aging population can be assuaged by ever closer safe human-robot collaboration (HRI): to improve productivity, reduce health limitations and provide services. HRI and safety are both major topics in the Work Programme. Safety regulations will be a barrier to cobot deployment unless they are easy to access, understand and apply. COVR collates existing safety regulations relating to cobots in e.g. manufacturing and fills in regulatory gaps for newer cobot fields e.g. rehabilitation to present detailed safety assessment instructions to coboteers. Making the safety assessment process clearer allows cobots to be used with more confidence in more situations, increasing the variety of cobots on the market and the variety of services cobots can offer to the general population. TRYG provides a one-stop shop which uses a common approach to safety assessment and is valid across all fields and applications. TRYG will provide clear and simple online access to best-practice safety testing protocols via a user-friendly decision tree, guided by questions about the cobot and its intended behaviours. Resulting application-specific testing protocols specify how to assess safety and document compliance with regulations. We support coboteers by providing safety-relevant services based in well-equipped facilities at each partner site. TRYG services cover all stages of cobot development from design through final system sign-off to safety in use and maintenance, provided through consultancy, risk analysis, actual testing, workshops, courses, demonstrations, etc. – all designed to inspire people to increase cobot safety. All TRYG elements will be beta-tested by external cobot developers etc. financed by FSTP. By using project elements “live”, these FSTP beneficiaries not only develop their cobots further towards market, but also contribute their knowledge to the TRYG system and provide valuable feedback to both partners and standards developers.