The ENLACE project will focus on researching a new free-space optical link through the study of new integrated photonics (PIC) devices and circuits, and communication channels based on high repetition rate ultrashort pulse lasers. This new generation of links will enable Earth-to-Earth and Earth-to-Space-Earth laser communications under adverse atmospheric conditions, making a radical contribution to the development of future Internet infrastructure.

The main objective of this project is to design and develop an inline quality control system for color properties in the production of pre-painted metal coils (coil coating). This inline color measurement system will be based on remote illumination using supercontinuum fiber laser technology, scanning and synchronous detection immune to ambient light, and new proprietary sequential measurement algorithms. It will replace the manual measurement methods currently in use, thereby optimizing quality control processes and drastically reducing costs due to color inconsistencies in the supply chain.

In this context, the main objective of this project is to design and develop a new transmitter-receiver system based on an ultrashort pulse laser source, to be used as an effective Earth-to-Earth optical communication link under adverse atmospheric conditions and effective at distances greater than 2 km

The general objective of the STELA project is to research and develop an intelligent manufacturing system for processing materials at sub-millimeter levels (microprocessing) using laser technology as the manufacturing tool. This includes the research and development of a specially designed monitored fiber laser source for microprocessing, an integrated monitoring system within the optical head of the laser beam guide, and software that enables process control, modeling, and decision-making. The project aims to validate this system in three relevant applications in high-impact industrial sectors (automotive, water treatment, and food industry).

European Commission CONcISE is a new doctoral network set to bring to the market more data-efficient and quality-oriented techniques for biomedical optical imaging in biological tissues. The project follows an interdisciplinary approach, bringing together experts from academia and industry to develop novel, unconventional, and multi-dimensional computational imaging devices for biological tissues, where the hardware and the software are completely integrated and developed together.

To do this, FYLA will implement new technologies specialized in the design process (CAD) of lasers and their components, as well as in the calculation, analysis and simulation of their properties (CAM - CAE).

Will enable the new communication paradigm based on EONs and Super-Channels. The project has received funding from the call SME INSTRUMENT of the European Union’s Horizon 2020 program under the grant agreement Nº 826882.

The development of a Femtosecond (Fs) Temporally Coherent Supercontinuum (SC) Fiber Laser for Multi-Photon Microscopy (MPM). FYLA LASER S.L. has recruited a highly qualified specialist in photonics, that is not available in the Spanish job market, but whose knowledge has been crucial to open up opportunities for innovation and significant growth for the enterprise. This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No 739697.