The WAKEMEUP project objective is to set-up a pilot line for advanced microcontrollers with embedded non-volatile memory, design and manufacturing for the prototyping of innovative applications for the smart mobility and smart society domains. The already defined microcontrollers with 40nm embedded flash technology will be consolidated to build a solid manufacturing platform. Additional developments will be performed for the integration of memory, power management, connectivity, hard security on the same chip. The project will also target the industrialization of the embedded Phase Change Memory (PCM) technology built on top of the FDSOI 28nm logic process pilot line. The development of the ePCM will be driven by the final application requirements as well as decreasing the power consumption. The alternative memory solutions will be also studied as they have different - and complementary - traits in such areas as read/write speed, power and energy consumption, retention and endurance, and device density and benchmarked with the ePCM and the conventional eFlash. Continued advances in materials, device physics, architectures and design could further reduce the energy consumption of these memories. To achieve this goal of generating high value added semiconductor circuits in Europe in a breakthrough leading edge technology the project will deploy all the necessary activities to bring a new technology to an early industrial maturity stage. These activities encompass such developments as: technology enhancements for various specific application requirements such as wide temperature range and reliability, high security requests, high flexibility…, design enablment allowing first time silicon success, prototyping demonstrator products in the different application areas. In the WAKEMEUP project, new devices and systems will be developed by the application partners in automotive and secure based on FD-SOI and embedded digital technology to answer specific applications needs.

Exploratory behaviour lies at the core of human essence. Being confronted with novel terrain, materials, tools, or artistic creations, humans instinctively explore the unknown in order to acquire information about it, to make sense of it, to act on it, and to appreciate what is in front of them. This quest for understanding involves dynamic engagement like walking, observing, handling objects, and manipulating them to witness changes in sight, touch, or sound. Active exploration is pivotal in shaping our sensory experiences of the world. Yet, the mutual relationships between perceptual experiences and the dynamic structures of the multisensorial information generated by active exploration are still not well understood. This presents a significant scientific challenge in itself and for comprehending the human mind's workings in natural settings. It also negatively impacts the development of multisensory interactive technologies and the innovative design of immersive systems, as well as the modelling of intelligent adaptive behaviour, thereby affecting nearly every facet of our life, including healthcare, education, mobility, AI, robotics and culture. EXPLORA aims to uncover the mutual interactions between perceptual impacts and active exploration systematically, quantitatively, and empirically. We propose a paradigm shift, approaching perception of materials, objects, and space as dynamic interactions with complex ecological systems. Through our innovative, cross-sectoral, multi-disciplinary, and sustainable research and training programme, we aim to catalyse this shift, creating impact through transfer between science, engineering, design, arts and industry and by connecting multiple levels of STEAM (Science, Technology, Engineering, Arts, and Mathematics) education from middle schools to doctoral education to enhance talent and knowledge circulation across the European R&I (Research and Innovation) landscape.

The SILENSE project will focus on using smart acoustic technologies and ultrasound in particular for Human Machine- and Machine to Machine Interfaces. Acoustic technologies have the main advantage of a much simpler, smaller, cheaper and easier to integrate transducer. The ambition of this project is to develop and improve acoustic technologies beyond state-of-the-art and extend its application beyond the mobile domain to Smart Home & Buildings and Automotive domains. In this project, it will be proven that acoustics can be used as a touchless activation and control mechanism, by improvement or development of different smart acoustic technology blocks (hardware, software and system level) and integrate these blocks at system level. At technology level, the SILENSE project will: - Adapt and improve cost, performance, directivity and power consumption of (MEMS) acoustic transducers (incl. testing and qualification) - Heterogeneously integrate arrays of acoustic transducers with other electronics, using advanced (3D) packaging concepts - Develop smart algorithms for acoustical sensing, localization and communication - Combine voice and gesture control by means of the same transducer(s) At application level the SILENSE project will: - Apply acoustical sensing for touchless activation/control of mobile devices, wearables and, more in general, IoT nodes. The project links to Smart Systems Integration (B4), and refers also to application application-related topics, such as Smart Mobility and Smart Society. The application scope of the developed technologies is broader and comprises more societal domains, such as smart home/buildings, smart factories (i.e. Smart Production) and even Smart Health. Furthermore, a clear cross reference with Semiconductor Process, Equipment and Materials (B1) is established in view of the heterogeneous integration of technology blocks. Conventional silicon technologies will be combined with printed (flexible, large area electronics).