Experimental Efficient Influence Sampling of Quantum Processes
Abstract
Characterizing quantum processes is essential for unlocking the potential of quantum devices. However, standard quantum process tomography is resource-intensive and becomes infeasible on large-scale systems. Despite alternative approaches have been successfully developed for specific scenarios, they typically rely on multi-qubit gates or extensive prior knowledge, limiting their practicability and scalability. To address these challenges and complement existing approaches, we introduce , an efficient and scalable protocol that quantifies the of a quantum process on all qubit subsets using only single-qubit test gates, with sample complexity independent of system size. Using a photonic platform, we demonstrate influence sampling to identify high-influence qubits, reduce the full process to a smaller effective process, i.e., a junta approximation, and then learn it. We further confirm scalability by applying the protocol to a 24-qubit system and validate the junta approximation on a two-qubit process. These results establish influence sampling as a critical characterization technique, facilitating process learning and device assessment.
Cite
@article{arxiv.2506.07103,
title = {Experimental Efficient Influence Sampling of Quantum Processes},
author = {Hao Zhan and Zongbo Bao and Zekun Ye and Qianyi Wang and Minghao Mi and Penghui Yao and Lijian Zhang},
journal= {arXiv preprint arXiv:2506.07103},
year = {2026}
}
Comments
24 pages, 11 figures