Emergent self-adaptation in an integrated photonic neural network for backpropagation-free learning

Lugnan, Alessio; Aggarwal, Samarth; Brückerhoff-Plückelmann, Frank; Wright, C David; Pernice, Wolfram; Bhaskaran, Harish; Bienstman, Peter

doi:10.21203/rs.3.rs-3640994/v1

2023

DOI: 10.21203/rs.3.rs-3640994/v1

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Emergent self-adaptation in an integrated photonic neural network for backpropagation-free learning

Alessio Lugnan,

Samarth Aggarwal,

Frank Brückerhoff-Plückelmann

et al.

Abstract: Plastic self-adaptation, nonlinear recurrent dynamics and multi-scale memory are desired features in hardware implementations of neural networks, because they enable them to learn, adapt and process information similarly to the way biological brains do. In this work, we experimentally demonstrate these properties occurring in arrays of photonic neurons. Importantly, this is realised autonomously in an emergent fashion, without the need for an external controller setting weights and without explicit feedback of… Show more

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2024

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Exploring the potential of self-pulsing optical microresonators for spiking neural networks and sensing

Biasi,

Lugnan,

Micheli

et al. 2024

Commun Phys

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Photonic platforms are promising for implementing neuromorphic hardware due to their high processing speed, low power consumption, and ability to perform parallel processing. A ubiquitous device in integrated photonics, which has been extensively employed for the realization of optical neuromorphic hardware, is the microresonator. The ability of CMOS-compatible silicon microring resonators to store energy enhances the nonlinear interaction between light and matter, enabling energy efficient nonlinearity, fading memory and the generation of spikes via self-pulsing. In the self-pulsing regime, a constant input signal can be transformed into a time-dependent signal based on pulse sequences. Previous research has shown that self-pulsing enables the microresonator to function as an energy-efficient artificial spiking neuron. Here, we extend the experimental study of single and coupled microresonators in the self-pulsing regime to confirm their potential as building blocks for scalable photonic spiking neural networks. Furthermore, we demonstrate their potential for introducing all-optical long-term memory and event detection capabilities into integrated photonic neural networks. In particular, we show all-optical long-term memory up to at least 10 μ s and detection of input spike rates, which is encoded into different stable self-pulsing dynamics.

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Exploring the potential of self-pulsing optical microresonators for spiking neural networks and sensing

Biasi,

Lugnan,

Micheli

et al. 2024

Commun Phys

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show abstract

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Emergent self-adaptation in an integrated photonic neural network for backpropagation-free learning

Cited by 1 publication

References 38 publications

Exploring the potential of self-pulsing optical microresonators for spiking neural networks and sensing

Exploring the potential of self-pulsing optical microresonators for spiking neural networks and sensing

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