Ultra-small phase estimation via weak measurement technique with postselection

TL;DR

This paper develops a comprehensive theory for weak measurement-based parameter estimation with arbitrary postselection, demonstrating superior ultra-small time-delay estimation performance and robustness in experiments.

Contribution

It introduces a general theory encompassing previous models and experimentally verifies its advantages in ultra-small time-delay estimation.

Findings

Joint weak measurement outperforms weak value amplification for ultra-small delays

The scheme is robust against misalignment errors and wavelength dependence

Experimental results confirm theoretical predictions

Abstract

Weak measurement is a novel technique for parameter estimation with higher precision. In this paper we develop a general theory for the parameter estimation based on weak measurement technique with arbitrary postselection. The previous weak value amplification model and the joint weak measurement model are two special cases in our theory. Applying the developed theory, the time-delay estimation is investigated in both theory and experiment. Experimental results shows that when the time-delay is ultra small, the joint weak measurement scheme outperforms the weak value amplification scheme, and is robust against not only the misalignment errors but also the wavelength-dependence of the optical components. These results are consistent with the theoretical predictions that has not been verified by any experiment before.