Quantum trajectories for time-binned data and their closeness to fully conditioned quantum trajectories

Abstract

Quantum trajectories are dynamical equations for quantum states conditioned on the results of a time-continuous measurement, such as a continuous-in-time current yt. Recently there has been renewed interest in dynamical maps for quantum trajectories with time-intervals of finite size t. Guilmin et al. (unpublished) derived such a dynamical map for the (experimentally relevant) case where only the average current It over each interval is available. Surprisingly, this binned data still generates a conditioned state that is almost pure (for efficient measurements), with an impurity scaling as ( t)3. We show that, nevertheless, the typical distance of from F; yt -- the projector for the pure state conditioned on the full current -- is as large as ( t)3/2. We introduce another finite-interval dynamical map (``-map''), which requires only one additional real statistic, φt, of the current in the interval, that gives a conditioned state which is only ( t)2-distant from F; yt. We numerically verify these scalings of the error (distance from the true states) for these two maps, as well as for the lowest-order (It\o) map and two other higher-order maps. Our results show that, for a generic system, if the statistic φt can be extracted from experiment along with It, then the -map gives a smaller error than any other.