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Quantum Cross Entropy and Maximum Likelihood Principle

Quantum Physics 2022-10-25 v3 Information Theory Machine Learning High Energy Physics - Theory math.IT Machine Learning

Abstract

Quantum machine learning is an emerging field at the intersection of machine learning and quantum computing. Classical cross entropy plays a central role in machine learning. We define its quantum generalization, the quantum cross entropy, prove its lower bounds, and investigate its relation to quantum fidelity. In the classical case, minimizing cross entropy is equivalent to maximizing likelihood. In the quantum case, when the quantum cross entropy is constructed from quantum data undisturbed by quantum measurements, this relation holds. Classical cross entropy is equal to negative log-likelihood. When we obtain quantum cross entropy through empirical density matrix based on measurement outcomes, the quantum cross entropy is lower-bounded by negative log-likelihood. These two different scenarios illustrate the information loss when making quantum measurements. We conclude that to achieve the goal of full quantum machine learning, it is crucial to utilize the deferred measurement principle.

Keywords

Cite

@article{arxiv.2102.11887,
  title  = {Quantum Cross Entropy and Maximum Likelihood Principle},
  author = {Zhou Shangnan and Yixu Wang},
  journal= {arXiv preprint arXiv:2102.11887},
  year   = {2022}
}

Comments

Added discussion on extensivity and parallel processing. Acknowledgement modified to reflect truth

R2 v1 2026-06-23T23:26:59.345Z