Inverse design of unitary transmission matrices in silicon photonic coupled waveguide arrays using a neural adjoint model
Inverse design of unitary transmission matrices in silicon photonic coupled waveguide arrays using a neural adjoint model
The development of low-loss reconfigurable integrated optical devices enables further research into technologies including photonic signal processing, analogue quantum computing, and optical neural networks. Here, we introduce digital patterning of coupled waveguide arrays as a platform capable of implementing unitary matrix operations. Determining the required device geometry for a specific optical output is computationally challenging and requires a robust and versatile inverse design protocol. In this work we present an approach using high speed neural network surrogate-based gradient optimization, capable of predicting patterns of refractive index perturbations based on switching of the ultralow loss chalcogenide phase change material, antimony triselinide (Sb
2Se
3). Results for a 3 × 3 silicon waveguide array are presented, demonstrating control of both amplitude and phase for each transmission matrix element. Network performance is studied using neural network optimization tools such as data set augmentation and supplementation with random noise, resulting in an average fidelity of 0.94 for unitary matrix targets. Our results show that coupled waveguide arrays with perturbation patterns offer new routes for achieving programmable unitary operators, or Hamiltonians for quantum simulators, with a reduced footprint compared to conventional interferometer-mesh technology.
Sb Se, deep learning, inverse design, neural adjoint, phase change materials, programmable photonic devices
1480-1493
Radford, Thomas W.
71ac0576-afc9-43c4-b0bf-c51719afe551
Wiecha, Peter R.
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Politi, Alberto
cf75c0a8-d34d-4cbe-b9d5-e408c0edeeec
Zeimpekis, Ioannis
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Muskens, Otto L.
2284101a-f9ef-4d79-8951-a6cda5bfc7f9
Radford, Thomas W.
71ac0576-afc9-43c4-b0bf-c51719afe551
Wiecha, Peter R.
fb335482-9577-41af-a0ef-3988b7654c9b
Politi, Alberto
cf75c0a8-d34d-4cbe-b9d5-e408c0edeeec
Zeimpekis, Ioannis
df8606c0-5d27-46da-9e98-8296d6d7249a
Muskens, Otto L.
2284101a-f9ef-4d79-8951-a6cda5bfc7f9
Radford, Thomas W., Wiecha, Peter R., Politi, Alberto, Zeimpekis, Ioannis and Muskens, Otto L.
(2025)
Inverse design of unitary transmission matrices in silicon photonic coupled waveguide arrays using a neural adjoint model.
ACS Photonics, 12 (3), .
(doi:10.1021/acsphotonics.4c02081).
Abstract
The development of low-loss reconfigurable integrated optical devices enables further research into technologies including photonic signal processing, analogue quantum computing, and optical neural networks. Here, we introduce digital patterning of coupled waveguide arrays as a platform capable of implementing unitary matrix operations. Determining the required device geometry for a specific optical output is computationally challenging and requires a robust and versatile inverse design protocol. In this work we present an approach using high speed neural network surrogate-based gradient optimization, capable of predicting patterns of refractive index perturbations based on switching of the ultralow loss chalcogenide phase change material, antimony triselinide (Sb
2Se
3). Results for a 3 × 3 silicon waveguide array are presented, demonstrating control of both amplitude and phase for each transmission matrix element. Network performance is studied using neural network optimization tools such as data set augmentation and supplementation with random noise, resulting in an average fidelity of 0.94 for unitary matrix targets. Our results show that coupled waveguide arrays with perturbation patterns offer new routes for achieving programmable unitary operators, or Hamiltonians for quantum simulators, with a reduced footprint compared to conventional interferometer-mesh technology.
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radford-et-al-2025-inverse-design-of-unitary-transmission-matrices-in-silicon-photonic-coupled-waveguide-arrays-using-a
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e-pub ahead of print date: 12 February 2025
Keywords:
Sb Se, deep learning, inverse design, neural adjoint, phase change materials, programmable photonic devices
Identifiers
Local EPrints ID: 501960
URI: http://eprints.soton.ac.uk/id/eprint/501960
ISSN: 2330-4022
PURE UUID: 70ab460e-17f6-4eb1-9327-dd58dd646921
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Date deposited: 12 Jun 2025 17:01
Last modified: 22 Aug 2025 02:10
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Contributors
Author:
Thomas W. Radford
Author:
Peter R. Wiecha
Author:
Ioannis Zeimpekis
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