High-precision laser spectrum analyzer via digital decoherence
Abstract
With the continuous advancement of laser technology, accurately evaluating the noise spectrum of high-performance lasers has become increasingly challenging. In this work, we demonstrate a high-precision laser spectrum analyzer based on the proposed digital decoherence method, which can precisely measure the frequency noise spectrum of sub-Hz linewidth lasers. In addition, it has broad wavelength compatibility, which enables convenient switching between lasers with different center wavelengths. Its performance is validated through measurements of ultra-stable lasers. Based on the measured frequency noise power spectral density, a beta-line linewidth is determined to be 570 mHz at 10-second observation time, and the minimum observable linewidth is calculated to be 133 mHz. The system's noise floor is evaluated to be 210 mHz beta-line linewidth at 25-second observation time, and a minimum observable linewidth of 39 mHz.
Cite
@article{arxiv.2505.20986,
title = {High-precision laser spectrum analyzer via digital decoherence},
author = {Zhongwang Pang and Chunyi Li and Hongfei Dai and Wenlin Li and Dongqi Song and Fei Meng and Yige Lin and Bo Wang},
journal= {arXiv preprint arXiv:2505.20986},
year = {2025}
}
Comments
5 figures