EMXYS Init Page

Precision gravimeter for measuring gravitational differentials using micro-satellites in low Earth orbit

Precision gravimeter for measuring gravitatory differentials using micro-satellite in low earth orbit - IMIDTA/2022/42 project carried out with the help of the Valencian Institute of Business Competitiveness (IVACE is Instituto Valenciano de Competitividad Empresarial) under the I+D PYME program (PIDI-CV) 2022.

The project has been co-financed by the European Regional Development Fund (FEDER) within the FEDER operational program of the Valencian Community 2014-2020 for which it has awarded a grant of €36,682.82.

ODALISS Ground Station

Implementation of a ground station with optical and radio links for communication with mini and microsatellite platforms – iminod/2022/112 project carried out with the help of the Valencian Institute of Business Competitiveness (IVACE is Instituto Valenciano de Competitividad Empresarial) under the program Innovación de PYME (INNOVA-CV).

The project has been co-financed by the European Regional Development Fund (FEDER) within the FEDER operational program of the Valencian Community 2021 – 2027 for which it has awarded a grant of €40,388.21.

Mini-satellite platform with high computational performances for artificial intelligence applications at the edge (edge ai) from Space

EdgeAISat project implies a quantum leap in computational performance for smallsats. Under this project, EMXYS is developing a disruptive satellite architecture addressed for high computational performance applications like AI and on-board sensor data processing. This architecture, combined with ODALCOM optical communications will unleash unprecedent applications in space computing. INNEST/2023/369.

The project has been co-financed by the European Regional Development Fund (FEDER) within the FEDER operational program of the Valencian Community 2021 – 2027 for which it has awarded a grant of €227.847,68.

Flight model of the power electronics system of a high-performance computational microsatellite high performance computational microsatellite platform. IMINOD/2023/11

Power system for a 3 or 6 unit Cubesat microsatellite to meet the energy demand of high performance data processing systems by providing peak power when required and ensuring the energy balance of the platform during successive orbits. The system consists of solar panels, storage system (batteries) and power management and protection module adapted to a standard Cubesat 3U and 6U structure.

The project has been co-financed by the European Regional Development Fund (FEDER) within the FEDER operational program of the Valencian Community 2021 – 2027 for which it has awarded a grant of 51.882,58€

Flight model of an in-orbit position-control computer for high-performance computational satellite platforms. IMIDTA/2023/39

A high-performance computational computer designed for Cubesat-type micro-satellites in low earth orbit (LEO), capable of real-time processing of images and data acquired by on-board sensors, and of acting on the altitude control to optimally position the satellite. It has an autonomous capability to respond to events in orbit and to improve the acquisition of new data. The system includes GPS and magnetometer for accurate orbital position estimation and has a set of three magnetorker and a 3-axis accelerometer for orientation control and platform stabilization.

The project has been co-financed by the European Regional Development Fund (FEDER) within the FEDER operational program of the Valencian Community 2021 – 2027 for which it has awarded a grant of 30.949,65€

NEUROMORPHIC ARTIFICIAL INTELLIGENCE PROCESSOR FOR ARTIFICIAL VISION IN AEROSPACE APPLICATIONS INNEST/2025/365

A high-performance neuromorphic artificial intelligence processor designed for onboard image processing in small satellite platforms operating in low Earth orbit (LEO). The system enables real-time vision processing directly on board, reducing data downlink requirements and increasing mission autonomy. Based on a heterogeneous RISC-V and neuromorphic architecture implemented with low-cost COTS components, the processor combines high computational efficiency with low power consumption, mass and volume. The design incorporates advanced radiation fault-tolerance techniques at hardware and software level, enabling reliable operation in the space environment and extending mission lifetime. The solution is aimed at Earth Observation missions, including environmental monitoring and emergency response applications.

The project has been co-financed by the European Regional Development Fund (FEDER) within the FEDER Operational Programme of the Valencian Community 2021–2027, with a granted contribution of 85,013.70 €.