Wavelength-dependent speckle multiplexing for imaging through opacity

Wavelength-dependent speckle multiplexing for imaging through opacity

•Wavelength-dependent speckle multiplexing can suppress coherent background noise.•Tunable laser and multimode fibre provide the decorrelated speckle illumination.•Partially spatially coherent light also enables speckle correlated imaging.•A broadband multiwavelength laser is favourable for the mult...

Full description

Saved in:
Bibliographic Details
Published in:Optics and lasers in engineering Vol. 141; p. 106567
Main Authors: Ma, Rui, Wang, Zhao, Wang, Wen Yu, Zhang, Yong, Liu, Jun, Zhang, Wei Li, Gomes, Anderson S L, Fan, Dian Yuan
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-06-2021
Subjects:
Illumination technique
Memory effect
Multimode fibre
Spatial coherence
Speckle correlated imaging
Multimode fibre
Speckle correlated imaging
Memory effect
Spatial coherence
Illumination technique
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•Wavelength-dependent speckle multiplexing can suppress coherent background noise.•Tunable laser and multimode fibre provide the decorrelated speckle illumination.•Partially spatially coherent light also enables speckle correlated imaging.•A broadband multiwavelength laser is favourable for the multi-channel detection. Memory-effect-based speckle-correlated imaging through opacity has been exploited widely in recent years. Generally, spatially incoherent light sources are required to provide effective illumination that can eliminate the interference noise. Here, the wavelength-dependent speckle multiplexing (WDSM) technique is first proposed and demonstrated as an effective method to suppress the interference noise, thereby facilitating the use of partially spatially coherent light as an alternative promising illuminating source. In contrast to the conventional decoherent approach which often employs a rapidly rotating diffuser to reduce the spatial coherence of a spatially coherent light, the WDSM shows greatly enhanced structural robustness by combining a tunable laser and the speckle illumination using a multimode fibre. The proposed WDSM not only expands the scope of candidate light sources for speckle-correlated imaging based on the classical phase-retrieval algorithm, but also enables the multi-channel detection determined by the speckle spectral decorrelation, which would further facilitate the waveband selective light-matter detection through opacity. This work also combines the advantages of fibre optics and laser technology and enriches the potential applications of speckle-correlated imaging.
ISSN:0143-8166
1873-0302
DOI:10.1016/j.optlaseng.2021.106567