English

Quantum channel tomography and estimation by local test

Quantum Physics 2026-02-04 v2 Information Theory math.IT

Abstract

We study the estimation of an unknown quantum channel E\mathcal{E} with input dimension d1d_1, output dimension d2d_2 and Kraus rank at most rr. We establish a connection between the query complexities in two models: (i) access to E\mathcal{E}, and (ii) access to a random dilation of E\mathcal{E}. Specifically, we show that for parallel (possibly coherent) testers, access to dilations does not help. This is proved by constructing a local tester that uses nn queries to E\mathcal{E} yet faithfully simulates the tester with nn queries to a random dilation. As application, we show that: - O(rd1d2/ε2)O(rd_1d_2/\varepsilon^2) queries to E\mathcal{E} suffice for channel tomography to within diamond norm error ε\varepsilon. Moreover, when rd2=d1rd_2=d_1, we show that the Heisenberg scaling O(1/ε)O(1/\varepsilon) can be achieved, even if E\mathcal{E} is not a unitary channel: - O(min{d12.5/ε,d12/ε2})O(\min\{d_1^{2.5}/\varepsilon,d_1^2/\varepsilon^2\}) queries to E\mathcal{E} suffice for channel tomography to within diamond norm error ε\varepsilon, and O(d12/ε)O(d_1^2/\varepsilon) queries suffice for the case of Choi state trace norm error ε\varepsilon. - O(min{d11.5/ε,d1/ε2})O(\min\{d_1^{1.5}/\varepsilon,d_1/\varepsilon^2\}) queries to E\mathcal{E} suffice for tomography of the mixed state E(00)\mathcal{E}(|0\rangle\langle 0|) to within trace norm error ε\varepsilon.

Keywords

Cite

@article{arxiv.2512.13614,
  title  = {Quantum channel tomography and estimation by local test},
  author = {Kean Chen and Nengkun Yu and Zhicheng Zhang},
  journal= {arXiv preprint arXiv:2512.13614},
  year   = {2026}
}

Comments

22 pages; v2: revised the Discussion section

R2 v1 2026-07-01T08:25:44.885Z