Photonic Quantum-Enhanced Knowledge Distillation
Abstract
Photonic quantum processors naturally produce intrinsically stochastic measurement outcomes, offering a hardware-native source of structured randomness that can be exploited during machine-learning training. Here we introduce Photonic Quantum-Enhanced Knowledge Distillation (PQKD), a hybrid quantum photonic--classical framework in which a programmable photonic circuit generates a compact conditioning signal that constrains and guides a parameter-efficient student network during distillation from a high-capacity teacher. PQKD replaces fully trainable convolutional kernels with dictionary convolutions: each layer learns only a small set of shared spatial basis filters, while sample-dependent channel-mixing weights are derived from shot-limited photonic features and mapped through a fixed linear transform. Training alternates between standard gradient-based optimisation of the student and sampling-robust, gradient-free updates of photonic parameters, avoiding differentiation through photonic hardware. Across MNIST, Fashion-MNIST and CIFAR-10, PQKD traces a controllable compression--accuracy frontier, remaining close to teacher performance on simpler benchmarks under aggressive convolutional compression. Performance degrades predictably with finite sampling, consistent with shot-noise scaling, and exponential moving-average feature smoothing suppresses high-frequency shot-noise fluctuations, extending the practical operating regime at moderate shot budgets.
Cite
@article{arxiv.2603.14898,
title = {Photonic Quantum-Enhanced Knowledge Distillation},
author = {Kuan-Cheng Chen and Shang Yu and Chen-Yu Liu and Samuel Yen-Chi Chen and Huan-Hsin Tseng and Yen Jui Chang and Wei-Hao Huang and Felix Burt and Esperanza Cuenca Gomez and Zohim Chandani and William Clements and Ian Walmsley and Kin K. Leung},
journal= {arXiv preprint arXiv:2603.14898},
year = {2026}
}