English

Learning linear optical circuits with coherent states

Quantum Physics 2023-04-04 v1

Abstract

We analyze the energy and training data requirements for supervised learning of an MM-mode linear optical circuit by minimizing an empirical risk defined solely from the action of the circuit on coherent states. When the linear optical circuit acts non-trivially only on k<Mk<M unknown modes (i.e., a linear optical kk-junta), we provide an energy-efficient, adaptive algorithm that identifies the junta set and learns the circuit. We compare two schemes for allocating a total energy, EE, to the learning algorithm. In the first scheme, each of the TT random training coherent states has energy E/TE/T. In the second scheme, a single random MTMT-mode coherent state with energy EE is partitioned into TT training coherent states. The latter scheme exhibits a polynomial advantage in training data size sufficient for convergence of the empirical risk to the full risk due to concentration of measure on the (2MT1)(2MT-1)-sphere. Specifically, generalization bounds for both schemes are proven, which indicate the sufficiency of O(E1/2M)O(E^{1/2}M) training states (O(E1/3M1/3)O(E^{1/3}M^{1/3}) training states) in the first (second) scheme.

Keywords

Cite

@article{arxiv.2304.00107,
  title  = {Learning linear optical circuits with coherent states},
  author = {T. J. Volkoff and Andrew T. Sornborger},
  journal= {arXiv preprint arXiv:2304.00107},
  year   = {2023}
}

Comments

9 pages, 2 figures

R2 v1 2026-06-28T09:44:02.629Z