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Bibliographic Details
Main Authors: Tindall, Joseph, Fishman, Matthew T.
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2306.17837
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author Tindall, Joseph
Fishman, Matthew T.
author_facet Tindall, Joseph
Fishman, Matthew T.
contents Effectively compressing and optimizing tensor networks requires reliable methods for fixing the latent degrees of freedom of the tensors, known as the gauge. Here we introduce a new algorithm for gauging tensor networks using belief propagation, a method that was originally formulated for performing statistical inference on graphical models and has recently found applications in tensor network algorithms. We show that this method is closely related to known tensor network gauging methods. It has the practical advantage, however, that existing belief propagation implementations can be repurposed for tensor network gauging, and that belief propagation is a very simple algorithm based on just tensor contractions so it can be easier to implement, optimize, and generalize. We present numerical evidence and scaling arguments that this algorithm is faster than existing gauging algorithms, demonstrating its usage on structured, unstructured, and infinite tensor networks. Additionally, we apply this method to improve the accuracy of the widely used simple update gate evolution algorithm.
format Preprint
id arxiv_https___arxiv_org_abs_2306_17837
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Gauging tensor networks with belief propagation
Tindall, Joseph
Fishman, Matthew T.
Quantum Physics
Effectively compressing and optimizing tensor networks requires reliable methods for fixing the latent degrees of freedom of the tensors, known as the gauge. Here we introduce a new algorithm for gauging tensor networks using belief propagation, a method that was originally formulated for performing statistical inference on graphical models and has recently found applications in tensor network algorithms. We show that this method is closely related to known tensor network gauging methods. It has the practical advantage, however, that existing belief propagation implementations can be repurposed for tensor network gauging, and that belief propagation is a very simple algorithm based on just tensor contractions so it can be easier to implement, optimize, and generalize. We present numerical evidence and scaling arguments that this algorithm is faster than existing gauging algorithms, demonstrating its usage on structured, unstructured, and infinite tensor networks. Additionally, we apply this method to improve the accuracy of the widely used simple update gate evolution algorithm.
title Gauging tensor networks with belief propagation
topic Quantum Physics
url https://arxiv.org/abs/2306.17837