Activities per year
Abstract
Recent developments in photonics include efficient nanoscale optoelectronic components and novel methods for subwavelength light manipulation. Here, we explore the potential offered by such devices as a substrate for neuromorphic computing. We propose an artificial neural network in which the weighted connectivity between nodes is achieved by emitting and receiving overlapping light signals inside a shared quasi 2D waveguide. This decreases the circuit footprint by at least an order of magnitude compared to existing optical solutions. The reception, evaluation, and emission of the optical signals are performed by neuron-like nodes constructed from known, highly efficient III-V nanowire optoelectronics. This minimizes power consumption of the network. To demonstrate the concept, we build a computational model based on an anatomically correct, functioning model of the central-complex navigation circuit of the insect brain. We simulate in detail the optical and electronic parts required to reproduce the connectivity of the central part of this network using previously experimentally derived parameters. The results are used as input in the full model, and we demonstrate that the functionality is preserved. Our approach points to a general method for drastically reducing the footprint and improving power efficiency of optoelectronic neural networks, leveraging the superior speed and energy efficiency of light as a carrier of information.
Original language | English |
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Pages (from-to) | 2787-2798 |
Number of pages | 12 |
Journal | ACS Photonics |
Volume | 7 |
Issue number | 10 |
DOIs | |
Publication status | Published - 2020 |
Subject classification (UKÄ)
- Condensed Matter Physics
- Biophysics
Free keywords
- insect brain
- nanowire
- neural network
- optical interconnects
- optoelectronic device
- optoelectronic modeling
- phototransistor
- polarization anisotropy
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Mimicking insect navigation in a synthetic nanowire bee brain
Winge, D. (Speaker)
2021 Dec 6Activity: Talk or presentation › Public lecture/debate/seminar
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Mimicking insect navigation, on P1 scientific news
Winge, D. (Interviewee)
2021 Apr 8Activity: Other › Media participation
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Mimicking insect navigation in a synthetic nanowire bee brain
Winge, D. (Invited speaker)
2021 Feb 3Activity: Talk or presentation › Public lecture/debate/seminar