Physical limitations on the operation speed of electronic devices has motivated the search for alternative ways to process information. The past few years have seen the development of neuromorphic photonics — a branch of photonics where the physics of optical and optoelectronic devices is combined with mathematical algorithms of artificial neural networks. Such a symbiosis allows certain classes of computation prob„lems, including some involving artificial intelligence, to be solved with greater speed and higher energy efficiency than can be reached with electronic devices based on the von Neumann architecture. We review optical analog computing, photonic neural networks, and methods of matrix multiplication by optical means, and discuss the advantages and disadvantages of existing approaches.
Keywords: neuromorphic photonics, artificial intelligence, machine learning, reservoir computing, matrix—vector multiplication, photonic computing, neural networks, optical coprocessor, photonic tensor computing, optical Fourier transform, integrated photonics, Mach—Zehnder interferometer, ring resonators, waveguides PACS:07.05.Mh, 42.79.Hp (all) DOI:10.3367/UFNe.2023.07.039505 URL: https://ufn.ru/en/articles/2023/12/b/ 001172931200006 2-s2.0-85183055912 2023PhyU...66.1211M Citation: Musorin A I, Shorokhov A S, Chezhegov A A, Baluyan T G, Safronov K R, Chetvertukhin A V, Grunin A A, Fedyanin A A "Photonics approaches to the implementation of neuromorphic computing" Phys. Usp.66 1211–1223 (2023)
TY JOUR
TI Photonics approaches to the implementation of neuromorphic computing
AU Musorin, A. I.
AU Shorokhov, A. S.
AU Chezhegov, A. A.
AU Baluyan, T. G.
AU Safronov, K. R.
AU Chetvertukhin, A. V.
AU Grunin, A. A.
AU Fedyanin, A. A.
PB Physics-Uspekhi
PY 2023
JO Physics-Uspekhi
JF Physics-Uspekhi
JA Phys. Usp.
VL 66
IS 12
SP 1211-1223
UR https://ufn.ru/en/articles/2023/12/b/
ER https://doi.org/10.3367/UFNe.2023.07.039505
Received: 8th, November 2022, revised: 4th, July 2023, accepted: 5th, July 2023