FORTIKA aims to (1) minimise the exposure of small and medium sized businesses to cyber security risks and threats, and (2) help them successfully respond to cyber security incidents, while relieving them from all unnecessary and costly efforts of identifying, acquiring and using the appropriate cyber security solutions. To fulfil its vision the project adopts a security by design hybrid approach that adequately integrates hardware and software with business needs and behavioural patterns at individual and organisational level to: introduce a hardware-enabled middleware security layer as add-on to existing network gateways; orientate small business users to trusted cyber security services (through FORTIKA’s marketplace) packaged to tailored solutions for each enterprise and further extended to accommodate security intelligence and to encourage security-friendly behavioural and organisational changes. Ultimately, FORTIKA proposes a resilient overall cyber security solution that can be easily tailored and adjusted to the versatile and dynamically changing needs of small businesses. To this end, the project ambitiously aims to make systematic and extensive use of the existing service and product portfolio of security solution providers across Europe. Finally the introduction of a software-defined smart ecosystem in “FORTIKA Marketplace”, will provide the feature of a light mode solution, which will offer virtualized security services (with minimum downloading requirements). From their perspective, users (i.e. SMEs) may utilize a variety of services and share profiling information with the service providers in return for tailored security services aligned with their actual needs. The FORTIKA marketplace will also function as a single point of access for the profiling information for each SME. FORTIKA Cyber-security framework will be evaluated through five major types of SMEs and will be supported from 2 local SME/ICT clusters and 1 EU alliance.

PANOPTIS aims at increasing the resilience of the road infrastructures and ensuring reliable network availability under unfavourable conditions, such as extreme weather, landslides, and earthquakes. Our main target is to combine downscaled climate change scenarios (applied to road infrastructures) with simulation tools (structural/geotechnical) and actual data (from existing and novel sensors), so as to provide the operators with an integrated tool able to support more effective management of their infrastructures at planning, maintenance and operation level. Towards this, PANOPTIS aims to: - use high resolution modelling data for the determination and the assessment of the climatic risk of the selected transport infrastructures and associated expected damages; - use existing SHM data (from accelerometers, strain gauges etc.) with new types of sensor-generated data (computer vision) to feed the structural/geotechnical simulator; - utilize tailored weather forecasts (combining seamlessly all available data sources) for specific hot-spots, providing early warnings with corresponding impact assessment in real time; - develop improved multi-temporal, multi-sensor UAV- and satellite-based observations with robust spectral analysis, computer vision and machine learning-based damage diagnostic for diverse transport infrastructures; - design and implement a Holistic Resilience Assessment Platform environment as an innovative planning tool that will permit a quantitative resilience assessment through an end-to-end simulation environment, running “what-if” impact/risk/resilience assessment scenarios. The effects of adaptation measures can be investigated by changing the hazard, exposure and vulnerability input parameters; - design and implement a Common Operational Picture, including an enhanced visualisation interface and an Incident Management System. The PANOPTIS integrated platform (and its sub-modules) will be validated in two real case studies in Spain and in Greece.

The vision of TERMINET is to provide a novel next generation reference architecture based on cutting-edge technologies such as SDN, multiple-access edge computing, and virtualisation for next generation IoT, while introducing new, intelligent IoT devices for low-latency, market-oriented use cases. TERMINET’s primary intention is to bring (more efficient and accurate) decisions to the point of interest to better serve the final user targeting at applying distributed AI at the edge by using accelerated hardware and sophisticated software to support local AI model training using federated learning. Our solution aspires to reduce the complexity of the connecting vast number of heterogeneous devices through a flexible SDN-enabled middleware layer. It also aims to design, develop, and integrate novel, intelligent IoT devices such as smart glasses, haptic devices, energy harvesting modules, smart animal monitoring collars, AR/VR environments, and autonomous drones, to support new market-oriented use cases. Great expectation of the proposal is to foster AR/VR contextual computing by demonstrating applicable results in realistic use cases by using cutting-edge IoT-enabled AR/VR applications. By designing and implementing an IoT-driven decentralised and distributed blockchain framework within manufacturing, TERMINET aims to support maintenance and supply chain optimisation. Our solution intends to apply a vertical security by design methodology by meeting the privacy-preserving and trust requirements of the NG-IoT architecture. To foster standardisation activities for the IoT ecosystem, TERMINET will provide novel disruptive business models. For the evaluation of its wide applicability, TERMINET will validate and demonstrate six proof-of-concept, realistic use cases in compelling IoT domains such as the energy, smart buildings, smart farming, healthcare, and manufacturing.