On the Capability of Measurement-Based Quantum Feedback

TL;DR

This paper investigates the fundamental limits and capabilities of measurement-based quantum feedback control, addressing how measurement choices affect control performance and the maximum achievable system stabilization.

Contribution

It provides a theoretical framework and theorems analyzing the maximum potential and limitations of quantum feedback control in quantum systems.

Findings

Established theorems on asymptotic reachability of eigenstates

Analyzed the tradeoff between measurement-induced uncertainty and information gain

Provided guidelines for optimal measurement channel selection

Abstract

As a key method in dealing with uncertainties, feedback has been understood fairly well in classical control theory. But for quantum control systems, the capability of measurement-based feedback control (MFC) has not been investigated systematically. In contrast to the control of classical systems where the measurement effect is negligible, the quantum measurement will cause a quantum state to collapse, which will inevitably introduce additional uncertainties besides the system initial uncertainty. Therefore, there is a complicated tradeoff between the uncertainty introduced and the information gained by the measurement, and thus a theoretical investigation of the capability of MFC is of fundamental importance. In this paper, inspired by both the Heisenberg uncertainty principle for quantum systems and the investigation of the feedback capability for classical systems, we try to answer the following three basic questions: (i) How to choose the measurement channel appropriately? (ii) Is the MFC still superior to the open loop control in dealing with the system information uncertainties? and (iii) What is the maximum capability or limitation of the MFC? These questions will be answered theoretically by establishing several theorems concerning the asymptotic reachability of eigenstates of a typical class of Hamiltonian control mode.