Quantum (Nov 2024)

Phase-space negativity as a computational resource for quantum kernel methods

  • Ulysse Chabaud,
  • Roohollah Ghobadi,
  • Salman Beigi,
  • Saleh Rahimi-Keshari

DOI
https://doi.org/10.22331/q-2024-11-07-1519
Journal volume & issue
Vol. 8
p. 1519

Abstract

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Quantum kernel methods are a proposal for achieving quantum computational advantage in machine learning. They are based on a hybrid classical-quantum computation where a function called the quantum kernel is estimated by a quantum device while the rest of computation is performed classically. Quantum advantages may be achieved through this method only if the quantum kernel function cannot be estimated efficiently on a classical computer. In this paper, we provide sufficient conditions for the efficient classical estimation of quantum kernel functions for bosonic systems. These conditions are based on phase-space properties of data-encoding quantum states associated with the quantum kernels: negative volume, non-classical depth, and excess range, which are shown to be three signatures of phase-space negativity. We consider quantum optical examples involving linear-optical networks with and without adaptive non-Gaussian measurements, and investigate the effects of loss on the efficiency of the classical simulation. Our results underpin the role of the negativity in phase-space quasi-probability distributions as an essential resource in quantum machine learning based on kernel methods.