Polytope compatibility - from quantum measurements to magic squares
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Polytope compatibility - from quantum measurements to magic squares. / Bluhm, Andreas; Nechita, Ion; Schmidt, Simon.
arXiv preprint, 2023.Research output: Working paper › Preprint › Research
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TY - UNPB
T1 - Polytope compatibility - from quantum measurements to magic squares
AU - Bluhm, Andreas
AU - Nechita, Ion
AU - Schmidt, Simon
PY - 2023
Y1 - 2023
N2 - Several central problems in quantum information theory (such as measurement compatibility and quantum steering) can be rephrased as membership in the minimal matrix convex set corresponding to special polytopes (such as the hypercube or its dual). In this article, we generalize this idea and introduce the notion of polytope compatibility, by considering arbitrary polytopes. We find that semiclassical magic squares correspond to Birkhoff polytope compatibility. In general, we prove that polytope compatibility is in one-to-one correspondence with measurement compatibility, when the measurements have some elements in common and the post-processing of the joint measurement is restricted. Finally, we consider how much tuples operators with appropriate joint numerical range have to be scaled in the worst case in order to become polytope compatible and give both analytical sufficient conditions and numerical ones based on linear programming.
AB - Several central problems in quantum information theory (such as measurement compatibility and quantum steering) can be rephrased as membership in the minimal matrix convex set corresponding to special polytopes (such as the hypercube or its dual). In this article, we generalize this idea and introduce the notion of polytope compatibility, by considering arbitrary polytopes. We find that semiclassical magic squares correspond to Birkhoff polytope compatibility. In general, we prove that polytope compatibility is in one-to-one correspondence with measurement compatibility, when the measurements have some elements in common and the post-processing of the joint measurement is restricted. Finally, we consider how much tuples operators with appropriate joint numerical range have to be scaled in the worst case in order to become polytope compatible and give both analytical sufficient conditions and numerical ones based on linear programming.
M3 - Preprint
BT - Polytope compatibility - from quantum measurements to magic squares
PB - arXiv preprint
ER -
ID: 346259563