Testing matrix product states
Abstract
Devising schemes for testing the amount of entanglement in quantum systems has played a crucial role in quantum computing and information theory. Here, we study the problem of testing whether an unknown state is a matrix product state (MPS) in the property testing model. MPS are a class of physically-relevant quantum states which arise in the study of quantum many-body systems. A quantum state comprised of qudits is said to be an MPS of bond dimension if the reduced density matrix has rank for each . When , this corresponds to the set of product states. For larger values of , this yields a more expressive class of quantum states, which are allowed to possess limited amounts of entanglement. In the property testing model, one is given identical copies of , and the goal is to determine whether is an MPS of bond dimension or whether is far from all such states. For the case of product states, we study the product test, a simple two-copy test previously analyzed by Harrow and Montanaro (FOCS 2010), and a key ingredient in their proof that for . We give a new and simpler analysis of the product test which achieves an optimal bound for a wide range of parameters, answering open problems of Harrow and Montanaro (FOCS 2010) and Montanaro and de Wolf (2016). For the case of , we give an efficient algorithm for testing whether is an MPS of bond dimension using copies, independent of the dimensions of the qudits, and we show that copies are necessary for this task. This lower bound shows that a dependence on the number of qudits is necessary, in sharp contrast to the case of product states where a constant number of copies suffices.
Keywords
Cite
@article{arxiv.2201.01824,
title = {Testing matrix product states},
author = {Mehdi Soleimanifar and John Wright},
journal= {arXiv preprint arXiv:2201.01824},
year = {2022}
}
Comments
30 pages, 2 figures