Conventional computing systems (like CPUs in PCs, Smartphones and etc.) will inevitably within the next 10 years reach a limit because of fundamental scientific reasons including limits on manufacturing, speed, density, transistor technology , power constraints . The most promising solution to this are the brain-inspired computing systems, so-called neuromorphic computing system (NCS). Implementation of NCSs using conventional transistor technology (CMOS) is area- and power-inefficient. Such inefficiencies have driven a significant effort to investigate the development of beyond-CMOS NCSs. The non-CMOS implementation of synapse has been researched to be implemented by spin-based materials (memristors, MTJs, STNOs and etc.). Despite some progress, still there is a huge difference (5-6 orders of magnitude) between the performance (operation/sec/Watt/cm3) of state-of-the-art NCS and human brain.
Neuromorphic computing market is expected to reach USD 1.7 billion by 2025 with an annual growth of 86%. Such growth shows the importance of neuromorphic computing and it is expected to find a huge market with the exponential growth of data processing, especially images and videos. In this respect, the social impact of PHOTON-NeuroCom’s technology can be tremendous. PHOTON-NeuroCom’s technology would allow for on-device computation, saving energy, speed, and improving privacy. PHOTON-NeuroCom will bring huge impact on society and EU economy, and the possibilities of new market creation is overwhelming, e.g. medical devices, edge devices, drones, space applications, military, IoT, smart vehicles, surveillance, smart cameras, financial forecasting, data mining, life-long self-learning machines etc.
The overall aim of PHOTON-NeuroCom was to realize a novel integration platform that combines photonic with current combination of the spin-based material and electronic (i.e. spintronic) in order to achieve an energy-efficient and high-speed brain-inspired computing system. The overall objectives of PHOTON-NeuroCom can be listed as:
1-Modelling the effect of heating on the dynamic and static behaviors of MTJ/STNO and the interaction between laser and MTJ/STNO
2-Design and simulation of a real-time laser-assisted MTJ/STNO-based NCS
3-Validating the models and designed systems by experimental results