English

Experimental sample-efficient quantum state tomography via parallel measurements

Quantum Physics 2024-10-22 v1

Abstract

Quantum state tomography (QST) via local measurements on reduced density matrices (LQST) is a promising approach but becomes impractical for large systems. To tackle this challenge, we developed an efficient quantum state tomography method inspired by quantum overlapping tomography [Phys. Rev. Lett. 124, 100401(2020)], which utilizes parallel measurements (PQST). In contrast to LQST, PQST significantly reduces the number of measurements and offers more robustness against shot noise. Experimentally, we demonstrate the feasibility of PQST in a tree-like superconducting qubit chip by designing high-efficiency circuits, preparing W states, ground states of Hamiltonians and random states, and then reconstructing these density matrices using full quantum state tomography (FQST), LQST, and PQST. Our results show that PQST reduces measurement cost, achieving fidelities of 98.68\% and 95.07\% after measuring 75 and 99 observables for 6-qubit and 9-qubit W states, respectively. Furthermore, the reconstruction of the largest density matrix of the 12-qubit W state is achieved with the similarity of 89.23\% after just measuring 243243 parallel observables, while 312=5314413^{12}=531441 complete observables are needed for FQST. Consequently, PQST will be a useful tool for future tasks such as the reconstruction, characterization, benchmarking, and properties learning of states.

Keywords

Cite

@article{arxiv.2409.12614,
  title  = {Experimental sample-efficient quantum state tomography via parallel measurements},
  author = {Chang-Kang Hu and Chao Wei and Chilong Liu and Liangyu Che and Yuxuan Zhou and Guixu Xie and Haiyang Qin and Guantian Hu and Haolan Yuan and Ruiyang Zhou and Song Liu and Dian Tan and Tao Xin and Dapeng Yu},
  journal= {arXiv preprint arXiv:2409.12614},
  year   = {2024}
}

Comments

To appear in PRL(2024)

R2 v1 2026-06-28T18:50:01.995Z