Information complementarity: A new paradigm for decoding quantum incompatibility
APA
Zhu, H. (2015). Information complementarity: A new paradigm for decoding quantum incompatibility. Perimeter Institute. https://pirsa.org/15070085
MLA
Zhu, Huangjun. Information complementarity: A new paradigm for decoding quantum incompatibility. Perimeter Institute, Jul. 28, 2015, https://pirsa.org/15070085
BibTex
@misc{ pirsa_PIRSA:15070085,
doi = {10.48660/15070085},
url = {https://pirsa.org/15070085},
author = {Zhu, Huangjun},
keywords = {Quantum Foundations},
language = {en},
title = {Information complementarity: A new paradigm for decoding quantum incompatibility},
publisher = {Perimeter Institute},
year = {2015},
month = {jul},
note = {PIRSA:15070085 see, \url{https://pirsa.org}}
}
Huangjun Zhu Fudan University
Abstract
The existence of observables that are incompatible or not jointly measurable is a characteristic feature of quantum mechanics, which is the root of a number of nonclassical phenomena, such as uncertainty relations, wave--particle dual behavior, Bell-inequality violation, and contextuality.
However, no intuitive criterion is available for determining the compatibility of even two (generalized) observables, despite the overarching importance of this problem and intensive efforts of many researchers over more than 80 years.
Here we introduce an information theoretic paradigm together with an intuitive geometric picture for decoding incompatible observables,
starting from two simple ideas: Every observable can only provide
limited information and information is monotonic under data
processing. By virtue of quantum estimation theory, we introduce a family of universal criteria for detecting incompatible observables and a natural measure of incompatibility, which are applicable to arbitrary number of arbitrary observables. Based on this framework, we derive a family of universal measurement uncertainty relations, provide a simple information theoretic explanation of quantitative wave--particle duality, and offer new perspectives for understanding Bell nonlocality, contextuality, and quantum precision limit.