Quantum Multi-Level Estimation of Functionals of Discrete Distributions

Abstract

We propose a quantum multi-level estimation framework for a functional Σi=1n f(pi) of a discrete distribution (pi)i=1n. We partition the values pi into logarithmically many intervals whose length decays exponentially. For each interval, we perform non-destructive singular value discrimination to isolate the relevant pi, enabling adaptive estimation of the partial sum over this interval. Unlike previous variable-time approaches, our method avoids high control overhead and requires only constant extra ancilla qubits. As an application, we present efficient quantum estimators for the q-Tsallis entropy of discrete distributions. Specifically: (i) For q > 1, we obtain a near-optimal quantum algorithm with query complexity (1/\1/(2(q-1)), 1\), improving the prior best O(1/1+1/(q-1)) due to Liu and Wang (SODA 2025; IEEE Trans. Inf. Theory 2026). (ii) For 0 < q < 1, we obtain a quantum algorithm with query complexity O(n1/q-1/2/1/q), exhibiting a quantum speedup over the near-optimal classical estimators due to Jiao, Venkat, Han, and Weissman (IEEE Trans. Inf. Theory 2017). Our results achieve, to our knowledge, the first near-optimal quantum estimators for parameterized q-entropy for non-integer q.