A Probabilistic Framework for Controlling Quantum Systems

TL;DR

This paper introduces a probabilistic control framework for quantum systems that accounts for uncertainties and noises, using probability density functions to optimize control strategies for desired outcomes.

Contribution

It presents a novel probabilistic control method for quantum systems, handling arbitrary pdfs and demonstrating effectiveness on molecular and spin systems.

Findings

Effective control of quantum systems with uncertainties

Application to real molecular and spin systems

Simplified control strategy demonstrated

Abstract

A new control method that considers all sources of uncertainty and noises that might affect the time evolutions of quantum physical systems is introduced. Under the proposed approach, the dynamics of quantum systems are characterised by probability density functions (pdfs), thus providing a complete description of their time evolution. Using this probabilistic description, the proposed method suggests the minimisation of the distance between the actual pdf that describes the joint distribution of the time evolution of the quantum system and the external electric field, and the desired pdf that describes the system target outcome. We start by providing the control solution for quantum systems that are characterised by arbitrary pdfs. The obtained solution is then applied to quantum physical systems characterised by Gaussian pdfs and the form of the optimised controller is elaborated. Finally, the proposed approach is demonstrated on a real molecular system and two spin systems showing the effectiveness and simplicity of the method.