Robust control of quantum systems by quantum systems

TL;DR

This paper introduces a coherent quantum feedback protocol that enables control and stabilization of quantum systems without information leakage, applicable to quantum computing, communication, and metrology.

Contribution

It develops a class of coherent feedback channels for quantum control, including a scheme that does not require knowledge of the target state, enabling autonomous quantum control.

Findings

Coherent feedback can steer quantum systems to desired states.

High-frequency weak interactions can effectively counteract noise.

A control scheme without target state knowledge is demonstrated.

Abstract

Quantum systems can be controlled by other quantum systems in a reversible way, without any information leaking to the outside of the system-controller compound. Such coherent quantum control is deterministic, is less noisy than measurement-based feedback control, and has potential applications in a variety of quantum technologies, including quantum computation, quantum communication and quantum metrology. Here we introduce a coherent feedback protocol, consisting of a sequence of identical interactions with controlling quantum systems, that steers a quantum system from an arbitrary initial state towards a target state. We determine the broad class of such coherent feedback channels that achieve convergence to the target state, and then stabilise as well as protect it against noise. Our results imply that also weak system-controller interactions can counter noise if they occur with suitably high frequency. We provide an example of a control scheme that does not require knowledge of the target state encoded in the controllers, which could be the result of a quantum computation. It thus provides a mechanism for autonomous, purely quantum closed-loop control.