Abstract
We study the performance of classical and quantum machine learning (ML) models in predicting outcomes of physical experiments. The experiments depend on an input parameter x and involve execution of a (possibly unknown) quantum process E. Our figure of merit is the number of runs of E required to achieve a desired prediction performance. We consider classical ML models that perform a measurement and record the classical outcome after each run of E, and quantum ML models that can access E coherently to acquire quantum data; the classical or quantum data are then used to predict the outcomes of future experiments. We prove that for any input distribution D(x), a classical ML model can provide accurate predictions on average by accessing E a number of times comparable to the optimal quantum ML model. In contrast, for achieving an accurate prediction on all inputs, we prove that the exponential quantum advantage is possible. For example, to predict the expectations of all Pauli observables in an n-qubit system ρ, classical ML models require 2^{Ω(n)} copies of ρ, but we present a quantum ML model using only O(n) copies. Our results clarify where the quantum advantage is possible and highlight the potential for classical ML models to address challenging quantum problems in physics and chemistry.
Highlights
We study the performance of classical and quantum machine learning (ML) models in predicting outcomes of physical experiments
We prove that for any input distribution DðxÞ, a classical ML model can provide accurate predictions on average by accessing E a number of times comparable to the optimal quantum ML model
We focus on the question of whether quantum ML can have a large advantage over classical ML: To achieve a small prediction error, can the optimal NQ in the quantum ML setting be much less than the optimal NC in the classical ML setting? For the purpose of this comparison, we disregard the runtime of the classical or quantum ML
Summary
We study the performance of classical and quantum machine learning (ML) models in predicting outcomes of physical experiments. Models that generate the predictions; we are only interested in how many times the process E must run during the learning phase in the quantum and classical settings. Over classical ML if the goal is to achieve a small average prediction error and if the efficiency is quantified by the number of times E is used in the learning process.
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