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Autori principali: Rozon, Pierre-Gabriel, Agarwal, Kartiek
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2508.00052
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author Rozon, Pierre-Gabriel
Agarwal, Kartiek
author_facet Rozon, Pierre-Gabriel
Agarwal, Kartiek
contents We introduce a variational scheme inspired by classical shadow tomography to compute ground state correlations of quantum spin Hamiltonians. Shadow tomography allows for efficient reconstruction of expectation values of arbitrary observables from a bag of repeated, randomized measurements, called snapshots, on copies of the state $ρ$. The prescription allows one to infer expectation values of $M$ $k-$local observables to accuracy $ε$ using just $N \sim 3^k \text{log}M /ε^2$ snapshots when measurements are performed in locally random bases. Turning this around, a bag of snapshots can be considered an efficient representation of the state $ρ$, particularly for estimating low-weight observables, such as terms in a local Hamiltonian needed to estimate the energy. Inspired by this, we consider a variational scheme wherein a bag of $N$ parametrized snapshots is used to represent the putative ground state of a desired local spin Hamiltonian and optimized to lower the energy with respect to it. Additional constraints in the form of positivity of reduced density matrices, motivated by work in quantum chemistry, are employed to ensure compatibility of the predicted correlations with the underlying Hilbert space. Unlike reduced density matrix approaches, learning the underlying distribution of measurement outcomes allows one to further correlations beyond those in the constrained density matrix. We show, with numerical results, that the proposed variational method can be parallelized, is efficiently simulable, and yields a more complete description of the ground state.
format Preprint
id arxiv_https___arxiv_org_abs_2508_00052
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Learning shadows to predict quantum ground state correlations
Rozon, Pierre-Gabriel
Agarwal, Kartiek
Quantum Physics
Computational Physics
We introduce a variational scheme inspired by classical shadow tomography to compute ground state correlations of quantum spin Hamiltonians. Shadow tomography allows for efficient reconstruction of expectation values of arbitrary observables from a bag of repeated, randomized measurements, called snapshots, on copies of the state $ρ$. The prescription allows one to infer expectation values of $M$ $k-$local observables to accuracy $ε$ using just $N \sim 3^k \text{log}M /ε^2$ snapshots when measurements are performed in locally random bases. Turning this around, a bag of snapshots can be considered an efficient representation of the state $ρ$, particularly for estimating low-weight observables, such as terms in a local Hamiltonian needed to estimate the energy. Inspired by this, we consider a variational scheme wherein a bag of $N$ parametrized snapshots is used to represent the putative ground state of a desired local spin Hamiltonian and optimized to lower the energy with respect to it. Additional constraints in the form of positivity of reduced density matrices, motivated by work in quantum chemistry, are employed to ensure compatibility of the predicted correlations with the underlying Hilbert space. Unlike reduced density matrix approaches, learning the underlying distribution of measurement outcomes allows one to further correlations beyond those in the constrained density matrix. We show, with numerical results, that the proposed variational method can be parallelized, is efficiently simulable, and yields a more complete description of the ground state.
title Learning shadows to predict quantum ground state correlations
topic Quantum Physics
Computational Physics
url https://arxiv.org/abs/2508.00052