English

Measurement Contextuality and Planck's Constant

Quantum Physics 2018-08-01 v1

Abstract

Contextuality is a necessary resource for universal quantum computation and non-contextual quantum mechanics can be simulated efficiently by classical computers in many cases. Orders of Planck's constant, \hbar, can also be used to characterize the classical-quantum divide by expanding quantities of interest in powers of \hbar---all orders higher than 0\hbar^0 can be interpreted as quantum corrections to the order 0\hbar^0 term. We show that contextual measurements in finite-dimensional systems have formulations within the Wigner-Weyl-Moyal (WWM) formalism that require higher than order 0\hbar^0 terms to be included in order to violate the classical bounds on their expectation values. As a result, we show that contextuality as a resource is equivalent to orders of \hbar as a resource within the WWM formalism. This explains why qubits can only exhibit state-independent contextuality under Pauli observables as in the Peres-Mermin square while odd-dimensional qudits can also exhibit state-dependent contextuality. In particular, we find that qubit Pauli observables lack an order 0\hbar^0 contribution in their Weyl symbol and so exhibit contextuality regardless of the state being measured. On the other hand, odd-dimensional qudit observables generally possess non-zero order 0\hbar^0 terms, and higher, in their WWM formulation, and so exhibit contextuality depending on the state measured: odd-dimensional qudit states that exhibit measurement contextuality have an order 1\hbar^1 contribution that allows for the violation of classical bounds while states that do not exhibit measurement contextuality have insufficiently large order 1\hbar^1 contributions.

Keywords

Cite

@article{arxiv.1711.08066,
  title  = {Measurement Contextuality and Planck's Constant},
  author = {Lucas Kocia and Peter Love},
  journal= {arXiv preprint arXiv:1711.08066},
  year   = {2018}
}
R2 v1 2026-06-22T22:53:23.680Z