Performance Measure for Optimal Quantum Control

TL;DR

This paper revisits time-energy uncertainty relations to propose a performance measure based on minimum evolution time, aiding quantum control optimization amidst environmental sensitivities and decoherence.

Contribution

It introduces a new minimum time performance measure for quantum control problems, grounded in time-energy uncertainty relations, with practical applications demonstrated.

Findings

The measure effectively evaluates quantum control strategies.

Application examples show its usefulness in optimizing quantum state control.

Results assist researchers in developing better quantum control protocols.

Abstract

The problem concerning the minimum time for an initial state to evolve up to a target state plays an important role in the Classic Optimal Control theory. In the quantum context, as quantum states are so sensitive to environmental influences, the problem is more complex, but its formulation and solution are decisive to implement quantum information processing systems. As is well known, the decoherence phenomenon is unavoidable and the time-energy uncertainty relation must be used to study quantum dynamics. Here, the time-energy uncertainty relations are revisited, being fundamental to propose performance measures based on minimum time evolution. A minimum time performance measure is definedfor quantum control problems. Then, some practical examples are considered and the minimum time performance measure is applied providing results that are supposed to be useful for researchers to pursue strategies to optimize the control of the states of a quantum system.