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Quantum Optical Neuron for Image Classification via Multiphoton Interference

Quantum Physics 2026-04-01 v1

Abstract

The rapid growth of machine learning is increasingly constrained by the energy and bandwidth limits of classical hardware. Optical and quantum technologies offer an alternative route, enabling high-dimensional, parallel information processing directly in the physical layer, particularly suited for imaging tasks. In this context, quantum photonic platforms provide both a natural mechanism for computing inner products and a promising path to energy-efficient inference in photon-limited regimes. Here, we experimentally demonstrate a camera-free quantum-optical images classifier that performs inference directly at the measurement layer using Hong-Ou-Mandel (HOM) interference of spatially programmable single photons. Two-photon coincidences directly report the overlap between an input image mode and a learned template, replacing pixel-resolved acquisition with a single global measurement. We realize both a single-perceptron quantum optical neuron and a two-neuron shallow network, achieving high accuracy on benchmark datasets with strong robustness to experimental noise and minimal hardware complexity. With a fixed measurement budget, performance remains insensitive to input resolution, demonstrating intrinsic robustness to the number of pixels, which would be impossible in a classical framework. This approach paves the way toward neuromorphic quantum photonic processors capable of extracting task-relevant information directly from HOM interference, with promising applications in remote object recognition, low-signal sensing, and photon-starved biological microscopy.

Keywords

Cite

@article{arxiv.2603.28879,
  title  = {Quantum Optical Neuron for Image Classification via Multiphoton Interference},
  author = {Giorgio Minati and Simone Roncallo and Simone Scrofana and Angela Rosy Morgillo and Nicoló Spagnolo and Chiara Macchiavello and Lorenzo Maccone and Valeria Cimini and Fabio Sciarrino},
  journal= {arXiv preprint arXiv:2603.28879},
  year   = {2026}
}
R2 v1 2026-07-01T11:44:48.271Z