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Research PaperResearchia:202607.08071

Provable learning separation for predicting time-evolution of quantum many-body systems

Rahul Bandyopadhyay

Abstract

Given that quantum computers are naturally suited to simulate the behavior of quantum many-body systems, an immediate question arises: can one formulate physically motivated quantum machine learning (QML) tasks that exhibit learning separations? We address this problem by studying the learnability of quantum many-body dynamics from the perspective of probably approximately correct (PAC)-learning. Concretely, we devise a supervised learning problem where the training set consists of specification...

Submitted: July 8, 2026Subjects: Machine Learning; Data Science

Description / Details

Given that quantum computers are naturally suited to simulate the behavior of quantum many-body systems, an immediate question arises: can one formulate physically motivated quantum machine learning (QML) tasks that exhibit learning separations? We address this problem by studying the learnability of quantum many-body dynamics from the perspective of probably approximately correct (PAC)-learning. Concretely, we devise a supervised learning problem where the training set consists of specifications of randomized stabilizer probe states, evolution times sampled uniformly from a polynomially large time interval [0,T][0,T], coupled with expectation values of certain observables evaluated on the resulting time-evolved state under an unknown Hamiltonian. For this learning task, we provide an efficient quantum procedure whose training phase learns the underlying Hamiltonian from short-time training samples, and whose deployment phase combines Hamiltonian simulation with the classical shadows protocol to perform inference on a newly given data point. By contrast, the existence of O(poly(n))O(\mathsf{poly}(n))-time instances ensures classical hardness: by embedding a BQP\mathsf{BQP}-complete computation into the polynomially long time-dynamics of a low-intersection variant of the Feynman-Kitaev clock Hamiltonian construction, we show that, for a certain family of input distributions, no randomized classical polynomial-time algorithm can fulfill our learning condition, unless BQPโІP/poly\mathsf{BQP}\subseteq\mathsf{P/poly}. Furthermore, we show that the classically hard instance maintains quantum learnability. We also give an interpretation of our results in learning-assisted certified quantum simulation. Taken together, our results demonstrate a rigorous learning separation for a natural ML task based on Hamiltonian evolution, while building connections between quantum learning theory, quantum simulation, and QML.


Source: arXiv:2607.06472v1 - http://arxiv.org/abs/2607.06472v1 PDF: https://arxiv.org/pdf/2607.06472v1 Original Link: http://arxiv.org/abs/2607.06472v1

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Date:
Jul 8, 2026
Topic:
Data Science
Area:
Machine Learning
Comments:
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