Past quantum states

TL;DR

This paper introduces the concept of the past quantum state, combining past and present information to improve predictions of measurement outcomes in quantum systems, generalizing previous theories and applying to various measurement scenarios.

Contribution

It presents the formalism of the past quantum state, integrating past and present quantum information to enhance measurement predictions beyond conventional states.

Findings

Better prediction of measurement outcomes using past quantum states

Generalizes pre- and post-selected quantum state theories

Applicable to systems with any measurement, evolution, and dissipation

Abstract

A density matrix {\rho}(t) yields probabilistic information about the outcome of measurements on a quantum system. We introduce here the past quantum state, which, at time T, accounts for the state of a quantum system at earlier times t < T. The past quantum state {\Xi}(t) is composed of two objects, {\rho}(t) and E(t), conditioned on the dynamics and the probing of the system until t and in the time interval [t, T], respectively. The past quantum state is characterized by its ability to make better predictions for the unknown outcome of projective and weak value measurements at t than the conventional quantum state at that time. On the one hand, our formalism shows how smoothing procedures for estimation of past classical signals by a quantum probe [M. Tsang, Phys. Rev. Lett. 102, 250403, (2009)] apply also to describe the past state of the quantum system itself. On the other hand, it generalizes theories of pre- and post-selected quantum states [Y. Aharonov and L. Vaidman, J. Phys. A: Math. Gen. 24, 2315 (1991)] to systems subject to any quantum measurement scenario, any coherent evolution, and any Markovian dissipation processes.