📝 SummarXiv

Abstract

Estimating properties of unknown unitary operations is a fundamental task in quantum information science. While full unitary tomography requires a number of samples to the unknown unitary scaling linearly with the dimension (implying exponentially with the number of qubits), estimating specific functions of a unitary can be significantly more efficient. In this paper, we present a unified framework for the sample-efficient estimation of arbitrary square integrable functions $f: \mathbf{U}(d) \to \mathbb{C}$, using only access to the controlled-unitary operation. We first provide a tight characterization of the optimal sample complexity when the accuracy is measured by the averaged bias over the unitary $\mathbf{U}(d)$. We then construct a sample-efficient estimation algorithm that becomes optimal under the Probably Approximately Correct (PAC) learning criterion for various classes of functions. Applications include optimal estimation of matrix elements of irreducible representations, the trace, determinant, and general polynomial functions on $\mathbf{U}(d)$. Our technique generalize the Hadamard test and leverage tools from representation theory, yielding both lower and upper bound on sample complexity.