Deep learning enabled laser speckle wavemeter with a high dynamic range
Abstract
The speckle pattern produced when a laser is scattered by a disordered medium has recently been shown to give a surprisingly accurate or broadband measurement of wavelength. Here it is shown that deep learning is an ideal approach to analyse wavelength variations using a speckle wavemeter due to its ability to identify trends and overcome low signal to noise ratio in complex datasets. This combination enables wavelength measurement at high precision over a broad operating range in a single step, with a remarkable capability to reject instrumental and environmental noise, which has not been possible with previous approaches. It is demonstrated that the noise rejection capabilities of deep learning provide attometre-scale wavelength precision over an operating range from 488 nm to 976 nm. This dynamic range is six orders of magnitude beyond the state of the art.
Keywords
Cite
@article{arxiv.1910.10702,
title = {Deep learning enabled laser speckle wavemeter with a high dynamic range},
author = {Roopam K. Gupta and Graham D. Bruce and Simon J. Powis and Kishan Dholakia},
journal= {arXiv preprint arXiv:1910.10702},
year = {2020}
}
Comments
23 pages, 7 figures