Optimal quantum metrology under energy constraints

Abstract: Quantum metrology promises enhanced precision in parameter estimation by exploiting quantum effects. The traditional framework of metrology commonly assumes unlimited access to resources, overlooking resource constraints in realistic scenarios. As such, the optimal strategies therein are often infeasible in practice. Here, we investigate quantum metrology where the total energy consumption of the probe state preparation, intermediate control operations, and the final measurement is subject to an energy constraint. We establish a comprehensive theoretical framework for characterizing energy-constrained quantum multi-step processes, which can be applied to other tasks of quantum information processing beyond metrology. Based on the framework, we develop a general optimization method for energy-constrained quantum metrology that determines the optimal precision as well as the corresponding optimal strategy. Applying our method to phase estimation, we show that while the estimation precision can benefit arbitrarily from increasing dimension with unconstrained energy, energy constraints result in an ultimate precision scaling of $1/E^2$ in an infinite-dimensional system, where $E$ is the available energy, which reveals that limited energy could be an essential barrier to precision improvement.