English

Resource-efficient algorithm for estimating the trace of quantum state powers

Quantum Physics 2025-09-03 v3

Abstract

Estimating the trace of quantum state powers, Tr(ρk)\text{Tr}(\rho^k), for kk identical quantum states is a fundamental task with numerous applications in quantum information processing, including nonlinear function estimation of quantum states and entanglement detection. On near-term quantum devices, reducing the required quantum circuit depth, the number of multi-qubit quantum operations, and the copies of the quantum state needed for such computations is crucial. In this work, inspired by the Newton-Girard method, we significantly improve upon existing results by introducing an algorithm that requires only O(r~)\mathcal{O}(\widetilde{r}) qubits and O(r~)\mathcal{O}(\widetilde{r}) multi-qubit gates, where r~=min{rank(ρ),ln(2k/ϵ)}\widetilde{r} = \min\left\{\text{rank}(\rho), \left\lceil\ln\left({2k}/{\epsilon}\right)\right\rceil\right\}. This approach is efficient, as it employs the r~\tilde{r}-entangled copy measurement instead of the conventional kk-entangled copy measurement, while asymptotically preserving the known sample complexity upper bound. Furthermore, we prove that estimating {Tr(ρi)}i=1r~\{\text{Tr}(\rho^i)\}_{i=1}^{\tilde{r}} is sufficient to approximate Tr(ρk)\text{Tr}(\rho^k) even for large integers k>r~k > \widetilde{r}. This leads to a rank-dependent complexity for solving the problem, providing an efficient algorithm for low-rank quantum states while also improving existing methods when the rank is unknown or when the state is not low-rank. Building upon these advantages, we extend our algorithm to the estimation of Tr(Mρk)\text{Tr}(M\rho^k) for arbitrary observables and Tr(ρkσl)\text{Tr}(\rho^k \sigma^l) for multiple quantum states.

Keywords

Cite

@article{arxiv.2408.00314,
  title  = {Resource-efficient algorithm for estimating the trace of quantum state powers},
  author = {Myeongjin Shin and Junseo Lee and Seungwoo Lee and Kabgyun Jeong},
  journal= {arXiv preprint arXiv:2408.00314},
  year   = {2025}
}

Comments

45 pages, 9 figures, 4 tables, The first two authors (MS, JL) contributed equally to this work

R2 v1 2026-06-28T18:00:07.165Z