Watershed segmentation based on gradient relief modification using variant structuring element

Xiao-peng Wang , Jing Li , Yue Liu

Optoelectronics Letters ›› 2014, Vol. 10 ›› Issue (2) : 152 -156.

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Optoelectronics Letters ›› 2014, Vol. 10 ›› Issue (2) : 152 -156. DOI: 10.1007/s11801-014-3209-5
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Watershed segmentation based on gradient relief modification using variant structuring element

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Abstract

Watershed segmentation is suitable for producing closed region contour and providing an accurate localization of object boundary. However, it is usually prone to over-segmentation due to the noise and irregular details within the image. For the purpose of reducing over-segmentation while preserving the location of object contours, the watershed segmentation based on morphological gradient relief modification using variant structuring element (SE) is proposed. Firstly, morphological gradient relief is decomposed into multi-level according to the gradient values. Secondly, morphological closing action using variant SE is employed to each level image, where the low gradient level sets use the large SE, while the high gradient level sets use the small one. Finally, the modified gradient image is recomposed by the superposition of the closed level sets, and watershed transform to the modified gradient image is done to implement the final segmentation. Experimental results show that this method can effectively reduce the over-segmentation and preserve the location of the object contours.

Keywords

Segmentation Result / Object Boundary / Gradient Image / Object Contour / Watershed Segmentation

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Xiao-peng Wang, Jing Li, Yue Liu. Watershed segmentation based on gradient relief modification using variant structuring element. Optoelectronics Letters, 2014, 10(2): 152-156 DOI:10.1007/s11801-014-3209-5

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

BeucherS, MeyerF. Optical Engineering, 1992, 34: 433
[2]

ZhaoC G, ZhuangT G. Pattern Recognition Letters, 2005, 26: 1256

[3]

XuS, LiuH, SongE. Journal of Digital Imaging, 2011, 24: 754

[4]

BleauA, LeonL J. Computer Vision and Image Understanding, 2000, 77: 317

[5]

MaragosP, VachierC. Overview of Adaptive Morphology: Trends and Perspectives16th IEEE International Conference on Image Processing, 2009, 2241
[6]

MeyerF. International Journal of Pattern Recognition and Artificial Intelligence, 2001, 15: 1089

[7]

GauchJ M. IEEE Transaction on Image Processing, 1999, 8: 69

[8]

XuJ-d, SunY-c, LiS, HuangJ, JiangY, JiangY-c. Journal of Optoelectronics ·Laser, 2012, 23: 956
[9]

DoriniL B, MinettoR, LeiteN J. IEEE Journal of Biomedical and Health Informatics, 2013, 17: 250

[10]

XuL, LuH. IEEE Transactions on Nanotechnology, 2013, 12: 51

[11]

YangX, LiH, ZhouX. IEEE Transactions on Circuits Systems I: Regular Papers, 2006, 53: 2405

[12]

MeyerF. Journal of Mathematical Imaging and Vision, 2004, 20: 59

[13]

WhitakerR T, XueX. X, Variable-Conductance, Level-Set Curvature for Image DenoisingIEEE International Conference on Image Processing, 2001, 3: 142
[14]

DagherI, El TomK. Image and Vision Computing, 2008, 26: 905

[15]

SofouA, MaragosP. IEEE Transactions on Image Processing, 2008, 17: 364

[16]

VachierC, MeyerF. Journal of Mathematical Imaging and Vision, 2005, 22: 251

[17]

VachierC, MeyerF. News from Viscousland8th International Symposium on Mathematical Morphology, 2007, 189
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