AID4SME will facilitate SMEs in developing combined AI and data solutions for large scale resource optimisation challenges for industries that have significant impact on the objectives of the Green Deal. Minimum 20 SMEs, selected through 2 open calls, will receive FSTP to develop these solutions with the support of a Community of Practice (COP). The ambition is to create a COP that will continue after the project lifetime. AID4SME brings together 9 technology blocks and low-TRL playgrounds from 4 scientific partners, to educate and support the SMEs. Additionally, 4 large industry partners (from automotive, whitegoods, battery and energy sector) provide real-life large scale resource optimization challenges that require combined AI and data solutions, and high-TRL playgrounds to integrate and demonstrate the solutions.AID4SME offers an open platform that is flexible to bring in challenges from outside the consortium. AID4SME provides the infrastructure and learning environment that enable the SMEs to solve the challenges, demonstrate solutions and grow into impactful enterprises. The technology blocks cover a wide area of AI & data technologies for the full cycle of data collection, creation of insights, decision support and automation. These technologies have the potential to have significant impact on the Green Transition and boost EU competitiveness for industries. AID4SME will collaborate with the AI-on-Demand platform to enrich its repository with the AID4SME tools and framework, while it is open to deploy the tools/frameworks already available on the AI-on-Demand platform for new use cases. AID4SME will assess the impact of the developed technologies on Green Deal objectives and on social and human aspects. AID4SME brings along partners who are experienced in re-skilling and up-skilling of SMEs and applying standardization as enabler for exploitation. The wide geographical coverage, with partners and DIHs from all across Europe, ensures maximum impact.

OPeraTIC will develop a highly efficient and modular manufacturing platform to boost the adoption of high-power Ultra-Short Pulsed Lasers, as a sustainable alternative to current surface processing. The OPeraTIC open, interoperable and expandable architecture will tackle the industrial entrance barriers of laser microstructuring of large 3D parts. OPeraTIC provides the required productivity/quality through different developments: (i) combination of advanced optical modules for beam transport and manipulation (ii) dexterous and precision robotic manipulator. iii) AI-enhanced process planning and adaptability. OPeraTIC proposes a modular and automated routing of optical components guaranteeing versatility and replicability, i.e beam delivery (polarization maintaining fiber), management (dynamic control beam shaping) and metrology (novel optical setups for product & process monitoring). On top of that, OPeraTIC will develop a system architecture for the upscaling of USPL machines to large envelope and complex trajectories, driven by a novel RAMI4.0-compliant controller (merging dexterous manipulation with high level CNC motion accuracy and full synchronization of motion, laser process and quality control). Finally, OPeraTIC proposes an I4.0-compliant platform for systematic data exchange and integrated bidirectional communication (Automation-ML and OPC-UA standards) between real environment and its digital representation. This end-to-end seamless connection enhances a Machine Intelligence Framework for the definition of Zero Defect Manufacturing strategies, empowered by AI and real-time monitorization and control, for process optimisation. A consortium of 4 top Research Institutions and 7 laser sector industry partners, backed by 2 adoption-oriented partners, will demonstrate OPeraTIC potential on relevant and high impact large-scale use-cases by 4 industrial end-users in the automotive, aeronautic, lighting, and white goods sectors.

The demand for electrical energy increases at a steady pace worldwide due to the growing and emerging applications such as server/telecom farms, 5G base station, more-electric aircrafts, consumer electronics, robotics, and electric vehicles. The volume and efficiency of the power converters utilized in these systems play a critical role for the fulfillment of this growth. Higher efficiency translates into more capacity utilization and less cooling efforts, whereas low volume and weight usually reduces the cost of the electronic components. Both of these aspects heavily depend on the innovations on the power topologies, control algorithms, magnetics, thermal substrates, and particularly power semiconductor switches. The power converter topologies in the literature have been invented to overcome or mitigate the large reverse recovery and output charge of Si power devices, while magnetics are optimized for switching frequencies that are achievable with Si power devices. However, the maximum efficiency and power density of Si based converters have already reached to its theoretical limit through innovations on the control and converter topologies. Recently, the adoption of the wide band-gap semiconductors has escalated the expectations from power electronics significantly, and initiated the transformation of the power architecture through new topologies and control innovations, while bringing new challenges in the high frequency domain. This research proposal is intended to innovate, design, and implement a new front-end PFC converter switched at >400 kHz to achieve best in-class efficiency and power density with targets of more than 98.5% peak efficiency and 85W/in3 enclosed power density at 3.7kW output power. The know-how and framework will then be engineered to meet certain industrial specs of various applications including the pre-regulator stage of server/telecom supplies, on-board chargers, industrial drives.

Wireless networks in buildings suffer from congestion, interference, security and safety concerns, restricted propagation and poor in-door location accuracy. The Internet of Radio-Light (IoRL) project develops a safer, more secure, customizable and intelligent building network that reliably delivers increased throughput (greater than 10Gbps) from access points pervasively located within buildings, whilst minimizing interference and harmful EM exposure and providing location accuracy of less than 10 cm. It thereby shows how to solve the problem of broadband wireless access in buildings and promotes the establishment of a global standard in ITU. Building landlords will be incentivized to find funding to realize this solution for their properties to increase their value resulting in a stimulated market for broadband networking products in buildings, benefiting society and stimulating the world Gross Domestic Product. IoRL project provides solutions to the two main barriers to develop this broadband networking solution in buildings because it: (i) Brings together a multi-disciplinary team of research institutions and industries in a collaborative project to develop and demonstrate this vision, who otherwise would not have assembled to achieve this goal; (ii) Develops a proof of concept demonstrator, which will act as the basis for standardization of a global solution. The starting point is the joint VLC demonstrator at Tsinghua University & ISEP, the mmWave at Cobham Wireless and the NFV/SDN at NCSR-Democratos. The challenges are to (i) Develop broadband communication solutions for buildings by integrating these technologies to exploit the pervasiveness and accessibility of the existing electric light access points, the broadband capacities of mmWave and VLC technologies and the flexibility of SDN/NFV; (ii) Industrially design a radio-light solution that can be integrated into the myriad of form factors of existing electric light systems and consumer products.

RELIANCE project aims to design and develop smart response self-disinfectant antimicrobial nanocoatings based y a new range of smart antimicrobial nanoparticles. Such nanoparticles will consist of mesoporous silica nanoparticles with metallic copper in their structure, modified with biobased bioactive compounds: Antimicrobial peptides (AMP’s) based on protein containing waste streams, and essential oils (EOs) coming from non-edible plants. The antibacterial action of these additives will be adjusted to the specific application, according to the dosages and durability requirements. In this way, two alternatives to incorporate the bioactive compounds will be considered: - The incorporation of the biobased EO into the porous substrate, to allow a controlled release (T or pH) of the bioactive compounds to the environment, - The attachment of the AMP to the nanoparticles surface, to allow a long-term action of the bioactive compound to the environment. RELIANCE project combines contact killing and leachable antibacterial actions ascribed to the additive with the non-sticking action due to the coatings formulation, thus providing an integral holistic solution to antimicrobial problems on different surfaces. The nature of the coatings, their characteristics (hydrophobicity and surface roughness) and their application methods (direct deposition by cold-atmospheric plasma, high throughput spraying or selective digital printing) will be specifically designed to allow not only the microbial repelling action, but also the adhesion of the coatings to different substrates commonly found in our living environments, such as metals, plastics or textiles, and to maximize their durability (in terms of performance and antibacterial properties). Beyond the present-day possibilities of conventional chemicals, sustainability and eco design criteria will be considered in the selection of the bioactives, and on the development of the nanocoatings.