A photonics perspective on computing with physical substrates

S. Abreu; I. Boikov; M. Goldmann; T. Jonuzi; A. Lupo; S. Masaad; L. Nguyen; E. Picco; G. Pourcel; A. Skalli; L. Talandier; B. Vettelschoss; E. A. Vlieg; A. Argyris; P. Bienstman; D. Brunner; J. Dambre; L. Daudet; J. D. Domenech; I. Fischer; F. Horst; S. Massar; C. R. Mirasso; B. J. Offrein; A. Rossi; M. C. Soriano; S. Sygletos; S. K. Turitsyn

doi:10.1016/j.revip.2024.100093

A photonics perspective on computing with physical substrates

S. Abreu, I. Boikov, M. Goldmann, T. Jonuzi, A. Lupo, S. Masaad, L. Nguyen, E. Picco, G. Pourcel, A. Skalli, L. Talandier, B. Vettelschoss, E. A. Vlieg, A. Argyris, P. Bienstman, D. Brunner, J. Dambre, L. Daudet, J. D. Domenech, I. FischerF. Horst, S. Massar, C. R. Mirasso, B. J. Offrein, A. Rossi, M. C. Soriano^*, S. Sygletos, S. K. Turitsyn

^*Corresponding author for this work

Artificial Intelligence

Research output: Contribution to journal › Review article › peer-review

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Abstract

We provide a perspective on the fundamental relationship between physics and computation, exploring the conditions under which a physical system can be harnessed for computation and the practical means to achieve this. Unlike traditional digital computers that impose discreteness on continuous substrates, unconventional computing embraces the inherent properties of physical systems. Exploring simultaneously the intricacies of physical implementations and applied computational paradigms, we discuss the interdisciplinary developments of unconventional computing. Here, we focus on the potential of photonic substrates for unconventional computing, implementing artificial neural networks to solve data-driven machine learning tasks. Several photonic neural network implementations are discussed, highlighting their potential advantages over electronic counterparts in terms of speed and energy efficiency. Finally, we address the challenges of achieving learning and programmability within physical substrates, outlining key strategies for future research.

Original language	English
Article number	100093
Number of pages	25
Journal	Reviews in Physics
Volume	12
Early online date	25-Jun-2024
DOIs	https://doi.org/10.1016/j.revip.2024.100093
Publication status	Published - Dec-2024

Keywords

Machine learning
Photonic neural networks
Physical substrates
Unconventional computing

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Abreu, S., Boikov, I., Goldmann, M., Jonuzi, T., Lupo, A., Masaad, S., Nguyen, L., Picco, E., Pourcel, G., Skalli, A., Talandier, L., Vettelschoss, B., Vlieg, E. A., Argyris, A., Bienstman, P., Brunner, D., Dambre, J., Daudet, L., Domenech, J. D., ... Turitsyn, S. K. (2024). A photonics perspective on computing with physical substrates. Reviews in Physics, 12, Article 100093. https://doi.org/10.1016/j.revip.2024.100093

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title = "A photonics perspective on computing with physical substrates",

abstract = "We provide a perspective on the fundamental relationship between physics and computation, exploring the conditions under which a physical system can be harnessed for computation and the practical means to achieve this. Unlike traditional digital computers that impose discreteness on continuous substrates, unconventional computing embraces the inherent properties of physical systems. Exploring simultaneously the intricacies of physical implementations and applied computational paradigms, we discuss the interdisciplinary developments of unconventional computing. Here, we focus on the potential of photonic substrates for unconventional computing, implementing artificial neural networks to solve data-driven machine learning tasks. Several photonic neural network implementations are discussed, highlighting their potential advantages over electronic counterparts in terms of speed and energy efficiency. Finally, we address the challenges of achieving learning and programmability within physical substrates, outlining key strategies for future research.",

keywords = "Machine learning, Photonic neural networks, Physical substrates, Unconventional computing",

author = "S. Abreu and I. Boikov and M. Goldmann and T. Jonuzi and A. Lupo and S. Masaad and L. Nguyen and E. Picco and G. Pourcel and A. Skalli and L. Talandier and B. Vettelschoss and Vlieg, {E. A.} and A. Argyris and P. Bienstman and D. Brunner and J. Dambre and L. Daudet and Domenech, {J. D.} and I. Fischer and F. Horst and S. Massar and Mirasso, {C. R.} and Offrein, {B. J.} and A. Rossi and Soriano, {M. C.} and S. Sygletos and Turitsyn, {S. K.}",

note = "Publisher Copyright: {\textcopyright} 2024 The Author(s)",

year = "2024",

month = dec,

doi = "10.1016/j.revip.2024.100093",

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Abreu, S, Boikov, I, Goldmann, M, Jonuzi, T, Lupo, A, Masaad, S, Nguyen, L, Picco, E, Pourcel, G, Skalli, A, Talandier, L, Vettelschoss, B, Vlieg, EA, Argyris, A, Bienstman, P, Brunner, D, Dambre, J, Daudet, L, Domenech, JD, Fischer, I, Horst, F, Massar, S, Mirasso, CR, Offrein, BJ, Rossi, A, Soriano, MC, Sygletos, S & Turitsyn, SK 2024, 'A photonics perspective on computing with physical substrates', Reviews in Physics, vol. 12, 100093. https://doi.org/10.1016/j.revip.2024.100093

TY - JOUR

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AU - Abreu, S.

AU - Boikov, I.

AU - Goldmann, M.

AU - Jonuzi, T.

AU - Lupo, A.

AU - Masaad, S.

AU - Nguyen, L.

AU - Picco, E.

AU - Pourcel, G.

AU - Skalli, A.

AU - Talandier, L.

AU - Vettelschoss, B.

AU - Vlieg, E. A.

AU - Argyris, A.

AU - Bienstman, P.

AU - Brunner, D.

AU - Dambre, J.

AU - Daudet, L.

AU - Domenech, J. D.

AU - Fischer, I.

AU - Horst, F.

AU - Massar, S.

AU - Mirasso, C. R.

AU - Offrein, B. J.

AU - Rossi, A.

AU - Soriano, M. C.

AU - Sygletos, S.

AU - Turitsyn, S. K.

PY - 2024/12

Y1 - 2024/12

N2 - We provide a perspective on the fundamental relationship between physics and computation, exploring the conditions under which a physical system can be harnessed for computation and the practical means to achieve this. Unlike traditional digital computers that impose discreteness on continuous substrates, unconventional computing embraces the inherent properties of physical systems. Exploring simultaneously the intricacies of physical implementations and applied computational paradigms, we discuss the interdisciplinary developments of unconventional computing. Here, we focus on the potential of photonic substrates for unconventional computing, implementing artificial neural networks to solve data-driven machine learning tasks. Several photonic neural network implementations are discussed, highlighting their potential advantages over electronic counterparts in terms of speed and energy efficiency. Finally, we address the challenges of achieving learning and programmability within physical substrates, outlining key strategies for future research.

AB - We provide a perspective on the fundamental relationship between physics and computation, exploring the conditions under which a physical system can be harnessed for computation and the practical means to achieve this. Unlike traditional digital computers that impose discreteness on continuous substrates, unconventional computing embraces the inherent properties of physical systems. Exploring simultaneously the intricacies of physical implementations and applied computational paradigms, we discuss the interdisciplinary developments of unconventional computing. Here, we focus on the potential of photonic substrates for unconventional computing, implementing artificial neural networks to solve data-driven machine learning tasks. Several photonic neural network implementations are discussed, highlighting their potential advantages over electronic counterparts in terms of speed and energy efficiency. Finally, we address the challenges of achieving learning and programmability within physical substrates, outlining key strategies for future research.

KW - Machine learning

KW - Photonic neural networks

KW - Physical substrates

KW - Unconventional computing

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DO - 10.1016/j.revip.2024.100093

M3 - Review article

AN - SCOPUS:85196803582

SN - 2405-4283

VL - 12

JO - Reviews in Physics

JF - Reviews in Physics

M1 - 100093

ER -

A photonics perspective on computing with physical substrates

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