LaserNet: a method of laser stripe center extraction under non-ideal conditions

Jiawei Shang; Yuzhou Chen; Jianhui Nie

doi:10.1364/AO.486107

Applied Optics
Vol. 62,
Issue 13,
pp. 3387-3397
(2023)
•https://doi.org/10.1364/AO.486107

LaserNet: a method of laser stripe center extraction under non-ideal conditions

Jiawei Shang, Yuzhou Chen, and Jianhui Nie

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Jiawei Shang, Yuzhou Chen, and Jianhui Nie, "LaserNet: a method of laser stripe center extraction under non-ideal conditions," Appl. Opt. 62, 3387-3397 (2023)

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Related Topics
Table of Contents Category
- Lasers, Optical Amplifiers, and Laser Optics
Optics & Photonics Topics
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The topics in this list come from the Optics and Photonics Topics applied to this article.

About this Article
History
- Original Manuscript: January 20, 2023
- Revised Manuscript: March 29, 2023
- Manuscript Accepted: April 2, 2023
- Published: April 24, 2023

Abstract

The extraction of the center of a laser stripe is a key step in line-structure measurement, where noise interference and changes in the surface color of an object are the main factors affecting extraction accuracy. To obtain sub-pixel level center coordinates under such non-ideal conditions, we propose LaserNet, a novel deep learning-based algorithm, to the best of our knowledge, which consists of a laser region detection sub-network and a laser position optimization sub-network. The laser region detection sub-network is used to determine potential stripe regions, and the laser position optimization sub-network uses the local image of these regions to obtain the accurate center position of the laser stripe. The experimental results show that LaserNet can eliminate noise interference, handle color changes, and give accurate results under non-ideal conditions. The three-dimensional reconstruction experiments further demonstrate the effectiveness of the proposed method.

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Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

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No.		Box 1	Box 2	Box 3	Box 4
MAE/Pixel	DTM	0.215	0.279	0.205	0.272
	GGM	0.156	0.241	0.144	0.200
	OUR	0.129	0.144	0.127	0.167
SD	DTM	0.148	0.199	0.129	0.191
	GGM	0.124	0.175	0.102	0.158
	OUR	0.078	0.101	0.083	0.126

No.		Original	N1	N2	N3	N4	N5	CM
MAE/Pixel	Steger	0.433	0.434	0.555	0.579	0.483	0.491	0.435
	DTM	0.297	0.306	0.451	0424	0.300	0.302	0.325
	GGM	0.259	0.273	0.282	0.302	0.289	\	0.403
	OUR	0.179	0.229	0.252	0.255	0.256	0.157	0.174
SD	Steger	0.312	0.308	0.399	0.397	0.339	0.347	0.315
	DTM	0.211	0.231	0.794	0.299	0.214	0.212	0.274
	GGM	0.186	0.194	0.206	0.219	0.257	\	0.430
	OUR	0.140	0.145	0.171	0.174	0.188	0.130	0.118

Size/Computing time(s)	Steger	DTM	GGM	LaserNet
$1600 \times 1200 P i x e l s$	2.054	4.224	0.004	0.317
$800 \times 600 P i x e l s$	0.513	1.875	0.002	0.131

No.	MAE/mm			SD
No.	GGM	OUR	RER	GGM	OUR	RER
Region 1	0.213	0.185	13.14%	0.146	0.132	9.59%
Region 2	0.254	0.234	7.87%	0.108	0.094	12.96%
Overall area	0.414	0.403	2.65%	0.282	0.269	4.61%

No.	MAE/mm			SD
No.	GGM	OUR	RER	GGM	OUR	RER
Region	0.233	0.217	6.87%	0.148	0.137	7.43%

No.	MAE/mm			SD
No.	GGM	OUR	RER	GGM	OUR	RER
Region 1	0.081	0.064	20.99%	0.064	0.046	28.13%
Region 2	0.223	0.216	3.14%	0.166	0.159	4.22%
Region 3	0.228	0.223	2.19%	0.198	0.192	3.03%

Abstract

Data availability

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Applied Optics