Experimental Efficient Influence Sampling of Quantum Processes

Abstract: Characterizing quantum processes paves the way for unlocking the full potential of quantum systems. However, quantum process tomography demands intensive resources and becomes infeasible on large-scale quantum devices. Other methods have explored advanced strategies, yet challenges in experimental feasibility and scalability persist. To address this issues, we introduce influence sampling that efficiently extracts the key \textit{influence} of a quantum process on qubit subsets using at most three distinct single-qubit test gates. Using a photonic platform, we experimentally demonstrate influence sampling and apply it to testing and learning quantum junta processes, determining whether a process acts non-trivially on only a subset of qubits and subsequently learning that process. In addition, we confirm the scalability of influence sampling by deploying it in larger systems. These results establish influence sampling as a powerful and scalable process characterization technique, facilitating efficient device assessment and noisy qubit identification.