Related papers: Maximal entropy approach for quantum state tomography

Maximal entropy approach for quantum state tomography

URL: http://arxiv.org/abs/2009.00815v2
Date: Thu, 3 Sep 2020 02:56:26 GMT
Title: Maximal entropy approach for quantum state tomography
Authors: Rishabh Gupta, Rongxin Xia, Raphael D. Levine and Sabre Kais
Abstract summary: Current quantum computing devices are noisy intermediate-scale quantum $($NISQ$)$ devices. Quantum tomography tries to reconstruct a quantum system's density matrix by a complete set of observables. We propose an alternative approach to quantum tomography, based on the maximal information entropy, that can predict the values of unknown observables.
Score: 3.6344381605841187
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Quantum computation has been growing rapidly in both theory and experiments. In particular, quantum computing devices with a large number of qubits have been developed by IBM, Google, IonQ, and others. The current quantum computing devices are noisy intermediate-scale quantum $($NISQ$)$ devices, and so approaches to validate quantum processing on these quantum devices are needed. One of the most common ways of validation for an n-qubit quantum system is quantum tomography, which tries to reconstruct a quantum system's density matrix by a complete set of observables. However, the inherent noise in the quantum systems and the intrinsic limitations poses a critical challenge to precisely know the actual measurement operators which make quantum tomography impractical in experiments. Here, we propose an alternative approach to quantum tomography, based on the maximal information entropy, that can predict the values of unknown observables based on the available mean measurement data. This can then be used to reconstruct the density matrix with high fidelity even though the results for some observables are missing. Of additional contexts, a practical approach to the inference of the quantum mechanical state using only partial information is also needed.

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