PRIVIDEMA represents an industry-driven initiative to advance privacy-preserving technologies in the application areas of cyber threat intelligence, data protection, and identity management. This multifaceted project operates across various research and innovation maturity levels, with the overarching goal of introducing more robust, user-friendly and scalable privacy and security technologies for the European ecosystem. Key components of PRIVIDEMA include: 1. Development of open-source tools, hosting networking events, and initiation of capacity-building efforts to democratize technology access and empower cybersecurity professionals. 2. Advancement of homomorphic encryption capabilities, implementation of hardware acceleration methods, and improvement of Fully Homomorphic Encryption (FHE) usability. 3. Creation and demonstration of a prototype European identity wallet featuring issuer and relaying party functionalities. 4. Development and demonstration of a prototype European privacy-preserving cyber threat data processing system, with real-world testing and validation of innovative technologies. Aligned with the objectives of Horizon Europe, PRIVIDEMA actively contributes to increased cybersecurity, data and network protection, and the establishment of robust digital infrastructures. The project distinguishes itself through its commitment to supporting SMEs as well as promoting open-source development, cross-disciplinary collaboration, and privacy-by-design principles. The solution-oriented approach positions PRIVIDEMA as a pivotal force in advancing cyber-resilient digitalization and the data economy in Europe. PRIVIDEMA's connection to various European strategic initiatives underscores its relevance, with a clear emphasis on real-world applications, innovation beyond the state-of-the-art, and a strategic trajectory toward market-ready solutions.

MILADO will provide a robust and universal technology platform for low-cost and large volume fabrication of mid infrared (MIR) lasers enabling novel sensors in medicine and production. Key innovation is the technology upscale of the epitaxy of Quantum-Cascade-Lasers (QCLs) on large area substrates and the development of concepts for direct III-V-epitaxy on silicon. Merging III-V and Si-photonics by integrating QCLs and Si-based MIR photonics using CMOS-based technology well-established but very costly III/V-technology-based manufacturing of QCL light sources for spectroscopic applications will be replaced by a cost-effective and scalable manufacturing technology on CEA’s CMOS Pilot Line bringing MIR technology out of its niche. Another building block of MILADO towards a general platform that can be extended for further integration of sensors and actuators in MEMS technology are MIR-PICs made from Ge/SiGe-structures for the definition of waveguides, combiners and any other passive devices required to handle the optical connection of QCLs. MILADO’s technology will open up new markets by enabling novel sensors for personal medical diagnostics or edge-sensors in chemical production. The versatility of the approach will be demonstrated in use cases covering process control and medical diagnostics reaching from the hospital to the patient covering waste anaesthetic gas detection, histopathology to biomarker monitoring.

This project envisions the wide-spread use of low-cost THz technology in our society, enabled by the proposed micromachined heterogeneous integration platform, which provides an unprecedented way to highly-integrated, volume-manufactuable, cost- and energy-efficient, reconfigurable submillimeter-wave and terahertz (THz) systems. The proposed THz integration platform is envisioned to initiate an important transition in industrial microwave-systems manufacturing and is expected to finally enable the large-scale commercialization of the heavily sought-after frequency space between 100 GHz and 1 THz. In line with technology convergence of advancing microwave semiconductor technology according to internal and external roadmaps, the proposed THz microsystem platform is envisioned to accommodate multiple generations of future THz products in different application fields. The concrete business and lead application case is THz microsystems enabling compact, low-cost point-to-point high-speed communication links in the frequency space between 100 GHz and 500 GHz, to be deployed in a scenario of a high-density small-cell base-station network providing ubiquitous high-speed internet access to mobile communication devices in urban environment. The key technology end-user driving the primary prototype development and demonstration of a complete THz communication link is Ericsson. A secondary prototype developed in M3TERA is on a multi-function adaptive THz sensor platform for different millimeter-wave sensing applications in society, including food quality control and food safety monitoring, medical diagnosis, and industrial sensing. The key manufacturing partner in this industry-driven proposal is the high-volume semiconductor and microsystems manufacturer IFAT, who also provides system packaging concepts. Project management of this 3-years project with 7 participants in 4 EU countries is done by a professional company with an exceptional career track in EU project management.

TThe 6GTandem project will demonstrate ultra-high-capacity coverage, off-load of lower frequency bands and new services such as sub-cm resolution sensing and positioning in high traffic areas by adding sub-THz carriers to lower frequency bands in a seamless, tightly coordinated fashion. The two frequency bands will form a network collaborating and supporting each other in a “tandem” configuration enabling an introduction of high capacity, energy efficient, sub-THz enabled services, while mitigating known drawbacks of the sub-THz frequency bands such as susceptibility to line-of-sight blockage, coverage, and cost. Deployment will be addressed through the introduction of a thin and light dielectric waveguide to distribute a sub-THz RF signal through a daisy chain of integrated low-power antenna units, referred to as a “radio stripe”. We will demonstrate the use of lower, sub-10 GHz frequency bands to support the sub-THz band with resilience and coverage and the implementation of a distributed MIMO system to extend the coverage of the sub-THz band as well as offering capacities in the order of Tbps system throughput. We will demonstrate the possibility to implement local fronthaul solutions for added sub-10GHz access points using the high bandwidth of sub-THz radio stripes. Key elements for 6GTandem: - A system defining an ‘aligned tandem’ dual-frequency distributed MIMO architecture - Medium-aware waveforms, transmission schemes and communication strategies for energy-efficient operation and development of cross-layer solutions to offer required service levels on the novel dual-frequency infrastructure - Novel, “radio stripe” hardware including transceivers at 130GHz-175GHz, packaging, integration, and plastic waveguide for a low-cost, easy-deployable sub-THz infrastructure - Conception of a combined low-frequency and sub-THz distributed MIMO system supporting joint high-resolution sensing, high-accuracy positioning, and high-resilience and reliability communication.

Software is everywhere and the productivity of Software Engineers has increased radically with the advent of new specification, design and programming paradigms and languages. The main objective of the project DECODER is to introduce radical solutions to increase productivity and by means of new languages that improve the situation by abstractions of the formalisms used today for requirements analysis and specification. We will develop a methodology and tools to improve the productivity of the software development process for medium-criticality applications in the domains of IoT, Cloud Computing, and Operating Systems by combining Natural Language Processing techniques, Modelling techniques and Formal Methods. The combination is a novel approach that permits a smooth transition from informal requirements engineering to deployment and maintenance phases. A radical improvement is expected from the management and transformation of informal data into material (herein called ‘knowledge’) that can be assimilated by any party involved in a development process. Thus, the DECODER project will 1) introduce new languages to represent knowledge in a more abstract manner, 2) develop transformations leading from informal material into specifications and code and vice-versa, 3) define and prototype a Persistent Knowledge Monitor for managing all relevant knowledge, and 4) develop a prototype IDE. The project will automate the transformation steps using existing techniques from the Big Data (knowledge extraction), Model-Driven Engineering (knowledge representation and refinement), and Formal Methods (specifications and proofs). The project will produce a novel Framework combining these techniques and demonstrate its efficiency on several uses cases belonging to the beforehand mentioned domains. The project expects an average benefit of 20% in terms of efforts on these use-cases and will provide recommendations on how to generalise the approach to other medium-criticality domains.