English

Run-length certificates in quantum learning: sample complexity and noise thresholds

Quantum Physics 2026-02-12 v1

Abstract

Quantum learning from state samples is often benchmarked in a fixed-budget paradigm, relating error to a prescribed number of copies. We instead adopt a stopping-time viewpoint: in minimal-feedback learning, the learning completion can be defined by an online run-length certificate extracted from a one-bit-per-copy record. As an instantiation, we analyze single-shot measurement learning (SSML), introduced in [Phys. Rev. A 98, 052302 (2018)] and [Phys. Rev. Lett. 126, 170504 (2021)], which tunes a unitary and halts after MHM_H consecutive successes. Viewing the halting as a sequential certification linking the observed counter to infidelity, we derive sample-complexity bounds that separate search (driving success probability toward unity) from certification (run statistics of consecutive successes). The resulting trade-off among MHM_H, dimension dd, and one-bit reliability clarifies when performance is control-limited versus certificate-limited. With label-flip noise probability qq, we find a sharp feasibility threshold: once qMH1qM_H \gtrsim 1, the expected halting time grows exponentially, making the learning completion impractical even under ideal control. More broadly, this shows that under severely constrained feedback, the certification can dominate sample complexity and small label noise becomes the information bottleneck. Finally, the near-optimal accuracy enabled by run-length certification aligns with the quantum-state-estimation (and equivalently, no-cloning) limits, expressed in the stopping-time terms.

Keywords

Cite

@article{arxiv.2602.10648,
  title  = {Run-length certificates in quantum learning: sample complexity and noise thresholds},
  author = {Jeongho Bang},
  journal= {arXiv preprint arXiv:2602.10648},
  year   = {2026}
}

Comments

19 pages, 3 figures

R2 v1 2026-07-01T10:31:31.868Z