Related papers: Shadow process tomography of quantum channels

Shadow process tomography of quantum channels

URL: http://arxiv.org/abs/2110.03629v4
Date: Tue, 11 Apr 2023 23:10:35 GMT
Title: Shadow process tomography of quantum channels
Authors: Jonathan Kunjummen, Minh C. Tran, Daniel Carney, Jacob M. Taylor
Abstract summary: Quantum process tomography is a critical capability for building quantum computers, enabling quantum networks, and understanding quantum sensors. The recent field of shadow tomography, applied to quantum states, has demonstrated the ability to extract key information about a state with onlyly many measurements. We make use of Choi isomorphism to directly apply rigorous bounds from shadow state tomography to shadow process tomography, and we find additional bounds on the number of measurements that are unique to process tomography.
Score: 0.6554326244334866
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Quantum process tomography is a critical capability for building quantum computers, enabling quantum networks, and understanding quantum sensors. Like quantum state tomography, the process tomography of an arbitrary quantum channel requires a number of measurements that scale exponentially in the number of quantum bits affected. However, the recent field of shadow tomography, applied to quantum states, has demonstrated the ability to extract key information about a state with only polynomially many measurements. In this work, we apply the concepts of shadow state tomography to the challenge of characterizing quantum processes. We make use of the Choi isomorphism to directly apply rigorous bounds from shadow state tomography to shadow process tomography, and we find additional bounds on the number of measurements that are unique to process tomography. Our results, which include algorithms for implementing shadow process tomography enable new techniques including evaluation of channel concatenation and the application of channels to shadows of quantum states. This provides a dramatic improvement for understanding large-scale quantum systems.

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