The Learnability of Unknown Quantum Measurements

TL;DR

This paper investigates the fundamental sample complexity limits for learning unknown quantum measurements, establishing bounds proportional to Hilbert space dimension and connecting quantum information tasks with classical machine learning techniques.

Contribution

It provides the first information-theoretic upper bounds on quantum measurement learnability using complexity measures and links quantum learning problems to neural network formulations.

Findings

Fat-shattering dimension bound scales linearly with Hilbert space dimension.

Classical machine learning techniques can be adapted for quantum measurement and state learning.

Explicit bounds derived for covering numbers and Rademacher complexities.

Abstract

Quantum machine learning has received significant attention in recent years, and promising progress has been made in the development of quantum algorithms to speed up traditional machine learning tasks. In this work, however, we focus on investigating the information-theoretic upper bounds of sample complexity - how many training samples are sufficient to predict the future behaviour of an unknown target function. This kind of problem is, arguably, one of the most fundamental problems in statistical learning theory and the bounds for practical settings can be completely characterised by a simple measure of complexity. Our main result in the paper is that, for learning an unknown quantum measurement, the upper bound, given by the fat-shattering dimension, is linearly proportional to the dimension of the underlying Hilbert space. Learning an unknown quantum state becomes a dual problem to ours, and as a byproduct, we can recover Aaronson's famous result [Proc. R. Soc. A 463:3089-3144 (2007)] solely using a classical machine learning technique. In addition, other famous complexity measures like covering numbers and Rademacher complexities are derived explicitly. We are able to connect measures of sample complexity with various areas in quantum information science, e.g. quantum state/measurement tomography, quantum state discrimination and quantum random access codes, which may be of independent interest. Lastly, with the assistance of general Bloch-sphere representation, we show that learning quantum measurements/states can be mathematically formulated as a neural network. Consequently, classical ML algorithms can be applied to efficiently accomplish the two quantum learning tasks.