An operator-algebraic formulation of self-testing
Abstract
We give a new definition of self-testing for correlations in terms of states on -algebras. We show that this definition is equivalent to the standard definition for any class of finite-dimensional quantum models which is closed, provided that the correlation is extremal and has a full-rank model in the class. This last condition automatically holds for the class of POVM quantum models, but does not necessarily hold for the class of projective models by a result of Baptista, Chen, Kaniewski, Lolck, Man{\v{c}}inska, Gabelgaard Nielsen, and Schmidt. For extremal binary correlations and for extremal synchronous correlations, we show that any self-test for projective models is a self-test for POVM models. The question of whether there is a self-test for projective models which is not a self-test for POVM models remains open. An advantage of our new definition is that it extends naturally to commuting operator models. We show that an extremal correlation is a self-test for finite-dimensional quantum models if and only if it is a self-test for finite-dimensional commuting operator models, and also observe that many known finite-dimensional self-tests are in fact self-tests for infinite-dimensional commuting operator models.
Cite
@article{arxiv.2301.11291,
title = {An operator-algebraic formulation of self-testing},
author = {Connor Paddock and William Slofstra and Yuming Zhao and Yangchen Zhou},
journal= {arXiv preprint arXiv:2301.11291},
year = {2023}
}
Comments
35 pages. v2: Typos corrected and references added. See video abstract at https://youtu.be/Rli8yM_KkNM