English

Time-averaged continuous quantum measurement

Quantum Physics 2025-05-28 v1

Abstract

The theory of continuous quantum measurement allows to reconstruct the state ρt\rho_t of a system from a continuous stochastic measurement record ItI_t. However, this truly continuous-time signal ItI_t is never available in practice. In experiments, one generally has access to its digitization, i.e., to a series of time averages IkI_k over finite intervals of duration Δt\Delta t. In this letter, we take this digitization seriously and define ρˉn\bar{\rho}_n as the best Bayesian estimate of the quantum state given (only) a digitized record (I1,,In)(I_1,\dots,I_n). We show that ρˉn+1\bar{\rho}_{n+1} can be computed recursively from In+1I_{n+1} and ρˉn\bar{\rho}_n using an exact formula. The latter can be evaluated numerically exactly, or used as the basis for a perturbative expansion into successive powers of Δt\sqrt{\Delta t}. This allows reconstructing quantum trajectories in regimes of coarse Δt\Delta t where existing methods fail, estimating parameters at fixed Δt\Delta t without bias, and directly sampling digitized quantum trajectories with schemes of arbitrarily high order.

Keywords

Cite

@article{arxiv.2505.20382,
  title  = {Time-averaged continuous quantum measurement},
  author = {Pierre Guilmin and Pierre Rouchon and Antoine Tilloy},
  journal= {arXiv preprint arXiv:2505.20382},
  year   = {2025}
}

Comments

5+2 pages, 3 figures

R2 v1 2026-07-01T02:40:50.506Z