Universal compilation for quantum state preparation and tomography

TL;DR

This paper introduces a universal compilation-based variational algorithm for efficient quantum state preparation and tomography, addressing challenges like circuit depth, noise, and optimization in low-depth quantum circuits.

Contribution

It proposes a novel variational algorithm utilizing universal compilation and Fubini-Study distance, demonstrating effectiveness in state preparation and tomography with various ansatzes and optimizers.

Findings

High efficiency in preparing entangled states like GHZ and W.

Comparable performance to shadow tomography in fidelity reconstruction.

Insights into the impact of circuit depth, noise, and error mitigation.

Abstract

Universal compilation is a training process that compiles a trainable unitary into a target unitary and it serves vast potential applications from quantum dynamic simulations to optimal circuits with deep-compressing, device benchmarking, quantum error mitigation, and so on. Here, we propose a universal compilation-based variational algorithm for the preparation and tomography of quantum states in low-depth quantum circuits. We apply the Fubini-Study distance to be a trainable cost function under various gradient-based optimizers, including the quantum natural gradient approach. We evaluate the performance of various unitary topologies and the trainability of different optimizers for getting high efficiency. In practice, we address different circuit ansatzes in quantum state preparation, including the linear and graph-based ansatzes for preparing different entanglement target states such as representative GHZ and W states. We also discuss the effect of the circuit depth, barren plateau, readout noise in the model, and the error mitigation solution. We next evaluate the reconstructing efficiency in quantum state tomography via various popular circuit ansatzes and reveal the crucial role of the circuit depth in the robust fidelity. The results are comparable with the shadow tomography method, a similar fashion in the field. Our work expresses the adequate capacity of the universal compilation-based variational algorithm to maximize the efficiency in the quantum state preparation and tomography. Further, it promises applications in quantum metrology and sensing and is applicable in the near-term quantum computers for verification of the circuits fidelity and various quantum computing tasks.