Discrimination Between Quantum Common Causes and Quantum Causality
Mingdi Hu, Yuexian Hou
TL;DR
This paper formalizes quantum common causes and causality, investigates their discriminability using a statistic C, and provides geometric insights to distinguish these quantum relationships.
Contribution
It extends the discrimination method using statistic C to general quantum cases and offers a geometric interpretation for better understanding.
Findings
C ranges for quantum common causes: [-1, 1/27]
C ranges for quantum causality: [-1/27, 1]
Geometric interpretation aids discrimination
Abstract
In classic cases, Reichenbach's principle implies that discriminating between common causes and causality is unprincipled since the discriminative results essentially depend on the selection of possible conditional variables. For some typical quantum cases, K.Reid . \href{https://www.nature.com/articles/nphys3266}{[Nat. Phys. 11, 414 (2015)]} presented the statistic which can effectively discriminate quantum common causes and quantum causality over two quantum random variables (i.e., qubits) and which only uses measurement information about these two variables. In this paper, we formalize general quantum common causes and general quantum causality. Based on the formal representation, we further investigate their decidability via the statistic in general quantum cases. We demonstrate that (i) if two qubits are influenced by…
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