Would you like to perform cutting-edge research at the
intersection between IC hardware and artificial intelligence? Do you want to explore a
new class of electronic-photonic components that mimics how biological neurons behave and helps reduce energy consumption and increase performance for AI hardware accelerators?
BackgroundRapid advances in artificial intelligence technologies have led to powerful models and algorithms that have revolutionized many applications across all fields of science and technology. Deep learning performed within artificial neural networks has yielded new ways to process data, leading to sophisticated systems with impressive functionality and benefits. However, conventional computing hardware is reaching its limits in terms of energy efficiency and speed. A new approach to computing hardware is needed.
Novel brain-inspired or neuromorphic chips working with biologically inspired spiking neural networks have gained attention as they promise highly efficient ways to process data. Important research effort has been dedicated to develop such neuromorphic systems in electronic and photonic hardware. We offer a research position (PhD or postdoc level) in this fast-paced research field, embedded within a world-class research group.
The integrated photonics fieldSimilar to electronic ICs, PICs are revolutionizing areas such as healthcare, communication and sensing, and have the potential to be disruptive to the whole society. Novel PIC components will have a big impact on the fields of sensing and processing. A diversity of PIC-based sensors have been proposed in the last years, such as environmental sensors (e.g. gas sensing), medical sensors (e.g. optical coherence tomography), fiber Bragg grating sensors for temperature or strain measurement, light detection and ranging (LiDAR) and others. Equally, novel PIC based solutions for processing data and performing computation had been proposed for information transport (equalization, pulse shaping), sensory data processing (Radar, LiDAR) and algorithmic problem solving (optimization, neural networks) .
Figure 1: Photonic integrated circuits on a semiconductor wafer.Recently, a new field of neuromorphic photonics is emerging, which aims to build artificial opto-electronic neurons that mimic the brain for processing information based on synaptic processes. Taking advantage of their threshold-based characteristics, neuromorphic photonic devices can also be used for spike-based processing and event-based sensing to allow recognition of patterns in an ultra-fast and energy-efficient manner.
We have made initial steps towards implementing opto-electronic neurons in InP integrated photonics. We demonstrated a first generation of resonant tunneling diodes (RTD), which display electrical excitable characteristics via tunneling effects. Full opto-electronic neuromorphic behavior was demonstrated by coupling the RTD with off-the-shelf external laser devices in cooperation with partners. See
M. Hejda et.al. Nanophotonics 12(5), 2022.We are now interested to pursue the monolithic integration of RTDs with integrated photonic devices to form electronic-photonic neurons on chip, thereby setting the grounds for future large-scale neuromorphic circuits.
The position links to a new European collaborative project SPIKEPro (Spiking Photonic-Electronic IC for Quick and Efficient Processing) within the European Innovation Council (EIC) framework. Close collaboration with the project partners, University of Strathclyde, University College London, TU Ilmenau and Hewlett-Packard Labs is foreseen.
The positionsThe research position focuses on the investigation of RTD-based neuromorphic photonics. The combination of RTDs with photonic devices such as lasers, photodetectors will result in threshold-based excitability making it possible to generate optical or electrical spikes, respectively, upon receiving low-amplitude stimuli. Their integration with other waveguide-based photonic components will be explored as well in order to advance towards a neuromorphic photonics platform. These positions will aim at proof-of-principle demonstration of spike-based neuromorphic sensing and processing (e.g. event-based sensing).
The work will comprise concept development, device design (incl. optical and electrical simulations), photonic chip layout, cleanroom fabrication and chip characterization in our laboratories. You will be part of the Photonic Integration (PhI) research group within the Eindhoven Hendrik Casimir Institute (EHCI). The research will be done in collaboration with European partners from academia and industry.