European projects

Find out more about running and closed European projects.

Running projects

Closed projects


The objective of the project is to improve the current state-of-the art silicon nitride (SiN) photonics pilot line for applications in life science. The project aims to establish a validated CMOS compatible SiN technology platform in the visible range for complex density integrated photonics integrated circuits (PICs).


The project aims to revolutionize in-vivo 3D imaging technique for non-invasive optical biopsy by considering medical needs with early diagnosis. This project will drive the next generation of optical coherence tomography (OC) system and will transform the use of OCT into widespread adoption in point-of-care diagnostics.  


ATHENIS_3D provides the industry’s first 3D integration of advanced More than Moore devices and More Moore devices (90nm and 14nm CMOS) with Through Silicon Vias (TSV) and Wafer Level Packaging (WLP) for harshest automotive conditions including temperatures up to 200C and voltages up to 200V. Cost savings from integration and a 5x reduction of PCB area will be shown.


This project brings together key partners with proven track-records to enhance the current state-of-the art system level image capture for diverse applications such as medical diagnostics and sustainable agriculture. The consortium will design new image sensors as well as focus on new silicon and system level developments.

EUREKA AntigenSense

The goal of this project is to develop fully disposable low cost electronic lateral flow system consisting of the strip and the electronic reading device. This type of solution could will bring the COVID-19 testing from laboratory application to the Point of Need.


This project aims to develop a reusable reader which is equipped with sensor and LED for reflective measurements. This new electronic rapid test can support health authorities at national and EU level in monitoring and mitigating the ongoing COVID-19 pandemic.


The EU funded Eniac project will design and develop Lithium-battery-pack systems which manage photovoltaic power feed efficiently and deliver optimized, reliable, low-cost and predictable performance. The BattMan project therefore focuses on essential elements and targets solar-powered, off-grid street lighting poles as a challenging demonstrator. It will be specified, simulated, designed, prototyped, demonstrated and validated in the project.


The aim of this project is to develop a capsule endoscope, which significantly reduces the amount of data generated by motion-controlled image acquisition. This means, on the one hand, an accelerated evaluation of the examination by the doctor, while at the same time, due to the saved data volume, allows the use of a high-resolution camera for better diagnosis and the storage of the image data in the capsule for easier handling.


The objective of this work is to develop a novel computer-aided design methodology for fast modeling and simulation of destructive substrate coupling effects in integrated mixed-signal, High Voltage (HV) and High Temperature (HT) smart power ICs for automotive applications.


The ENIAC JU project EPP combined research, development and innovation to demonstrate market readiness by industrial implementation at an early stage. Work to be performed included developing next generation power semiconductors based on 300mm wafers, setting up the required technologies as pilot line manufacturing, and demonstrating the thus achieved reliable and advantageous solutions for a wide range of ENIAC grand challenge application fields.


The ESTRELIA platform will enable a significant advancement of the technology capabilities for battery management systems design. A focused approach on battery management systems on the one hand but also cost effective system integration into vehicles on the other hand.


The mission of the MATTHEW project is to enable new applications and services on mobile devices. It will overcome the limitation of current passive NFC transmission technologies by active modulation and offer new ways of exchanging roles from one secure entity like a nanoSIM or a microSDTM card to another with novel security and privacy approaches.


The mission of the TRACE project is to assess the potential of movement tracking services to better plan and promote walking and cycling in cities, and develop tracking tools that will fuel the take up of walking and cycling measures. The project targets established measures to promote cycling and walking to the workplace, to school, for shopping purposes or simply for leisure.


PLASMOfab aims to develop CMOS compatible plasmonics in a generic planar integration process as the means to consolidate photonic and electronic integration. Wafer scale integration will be used by PLASMOfab to demonstrate low cost, volume manufacturing and high yield of powerful PICs. The new integration technology will unravel a series of innovations with profound benefits of enhanced light-matter interaction enabled by plasmonics in optical transmitters and biosensors modules.


MIRAGE aims to implement cost-optimized components for terabit optical interconnects introducing new multiplexing concepts through the development of a flexible, future-proof 3D “optical engine”. MIRAGE is a 3-year collaborative project on photonic integration that brings together eight leading European universities, research centers and companies. The project was launched in October 2012 and is co-funded by the European Commission through the Seventh Framework Programme (FP 7).