Information content for quantum states
Copyright policy )Information content for quantum states
A method for representing probabilistic aspects of quantum systems by means of a density function on the space of pure quantum states is introduced. In particular, a maximum entropy argument allows us to obtain a natural density function that only reflects the information provided by the density matrix. This result is applied to derive the Shannon entropy of a quantum state. The information theoretic quantum entropy thereby obtained is shown to have the desired concavity property, and to differ from the conventional von Neumann entropy. This is illustrated explicitly for a two-state system.
- University of Cambridge United Kingdom
- King's College London United Kingdom
- Kings College London, University of London United Kingdom
Quantum Physics, Measures of information, entropy, density function, Shannon entropy, 500, FOS: Physical sciences, 530, Foundations, quantum information and its processing, quantum axioms, and philosophy, Quantum computation, two-state system, concavity, Quantum Physics (quant-ph), maximum entropy argument
Quantum Physics, Measures of information, entropy, density function, Shannon entropy, 500, FOS: Physical sciences, 530, Foundations, quantum information and its processing, quantum axioms, and philosophy, Quantum computation, two-state system, concavity, Quantum Physics (quant-ph), maximum entropy argument
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