Laser & Optoelectronics Progress, Volume. 62, Issue 2, 0215002(2025)
Structured Light Centerline Extraction Method for Ice Surface Based on Normal Guidance
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Fig. 1. Boundary tracing schematic and chain code representation and coordinate diagram. (a) Schematic diagram of clockwise boundary tracing; (b) chain code representation and coordinate plot
Fig. 2. Light penetration images of the ice surface. (a) (b) Light spot interference and local magnification; (c) (d) line width variation and local magnification
Fig. 3. Laser and spot boundary diagrams. (a) (b) (c) Original laser and spot diagrams; (d) (e) (f) laser and spot contour diagrams
Fig. 8. Schematic diagram of accurate extraction of laser stripe center coordinates
Fig. 11. Original images of the surface of the ice body with diffused light spot and the extraction effect of multiple algorithms. (a) Original images;(b) gray gravity algorithm; (c) Steger algorithm; (d) skeleton algorithm; (e) algorithm of reference [13]; (f) algorithm of reference [16]; (g) algorithm of reference [17]; (h) proposed algorithm
Fig. 12. Original images of laser stripes with curvature change, comparison of extraction effects of multiple algorithms, and local enlargement images. (a) Original images;(b) gray gravity algorithm; (c) Steger algorithm; (d) skeleton algorithm; (e) algorithm of reference [13]; (f) algorithm of reference [16]; (g) algorithm of reference [17]; (h) proposed algorithm
Fig. 13. Original images of laser stripes with varying widths, comparison of extraction effects of various algorithms, and local enlargement images. (a) Original images;(b) gray gravity algorithm; (c) Steger algorithm; (d) skeleton algorithm; (e) algorithm of reference [13]; (f) algorithm of reference [16]; (g) algorithm of reference [17]; (h) proposed algorithm
Fig. 14. Schematic of laser stripes extraction on different ice surfaces. (a) Complex stripes with varying stripe line widths; (b) rough surface of the ice; (c) stripe boundaries are not obvious; (d) stripe line width widening
Fig. 17. Root mean square error of simulated light bar centers for multiple algorithms
Fig. 18. Frost ice sphere surface reconstruction effect. (a) Real image of frost ice; (b) 3D point cloud of frost ice surface
Table 1. Error analysis of laser-centered coordinates on the surface of the ice
View tableTable 1. Error analysis of laser-centered coordinates on the surface of the ice
Algorithm 1 2 3 4 5 6 7 Gray gravity 4.304 4.233 2.519 1.430 3.202 8.465 0.847 3.571 Steger 2.690 1.405 0.373 1.309 1.194 7.518 0.800 2.184 Skeleton 2.603 2.929 1.800 1.094 2.930 6.998 1.244 2.799 Algorithm of reference [ 13 ]3.395 0.829 1.113 1.030 1.532 4.486 0.520 1.843 Algorithm of reference [ 16 ]2.502 1.991 0.446 0.534 1.592 7.639 1.474 2.311 Algorithm of reference [ 17 ]2.494 1.431 0.679 1.110 1.298 7.378 0.430 2.117 Proposed algorithm 0.473 0.440 0.346 0.444 0.531 0.186 0.369 0.398
Table 2. Running time of different algorithms
View tableTable 2. Running time of different algorithms
Algorithm Picture number Average time 1 2 3 4 5 Gray gravity 6.3 5.8 6.0 5.7 5.9 5.94 Steger 159.4 148.8 150.3 150.6 150.1 151.84 Skeleton 9.6 9.0 8.8 9.3 9.7 9.28 Algorithm of reference [ 13 ]11.1 12.1 13.0 12.7 12.4 12.26 Algorithm of reference [ 16 ]21.6 21.4 20.7 19.9 20.5 20.82 Algorithm of reference [ 17 ]54.6 52.0 48.0 49.1 49.2 50.58 Proposed algorithm 24.4 24.1 23.5 22.1 21.3 23.08
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Tao Song, Guihua Liu, Huiming Huang, Yunxing Gong, Fuping Qin, Hao Xie. Structured Light Centerline Extraction Method for Ice Surface Based on Normal Guidance[J]. Laser & Optoelectronics Progress, 2025, 62(2): 0215002
Paper Information
Category: Machine Vision
Received: Mar. 5, 2024
Accepted: May. 22, 2024
Published Online: Jan. 3, 2025
The Author Email:
CSTR:32186.14.LOP240814
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