Abstract
One of the new emerging of ubiquitous manufacturing is Mass Customization. The combination of 3D scanning systems with mathematical technique makes possible the development of CAD system which can help the selection of good footwear for a given customer. During the surface reconstruction process, a mesh is calculated from points cloud. This mesh may have holes corresponding to deficiencies in the original point data. Although these data are given in an arbitrary position and orientation in 3D space. Moreover, there is a need to mesh segmentation in order to shape retrieval form shoe last data base. Thus to apply sophisticated modeling operation on data set, substantial preprocessing is usually required. In this paper first, we describe an algorithm for filling hole. Then all of the models are aligned and at the end the models are segmented in order to use for further analysis.
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References
Ture Savadkoohi, B., De Amicis, R.: Mass customization strategy in footwear industry. J. Adv. Comput. Sci. Appl. IJCSIA 5(2), 2250–3765 (2015)
Ture Savadkoohi, B., De Amicis, R.: 3D foot scanning in flexible manufacturing: comparisation and deformation solution. In: International Conference on Computer Graphics, Visualization, Computer Vision and Image processing. Las Palmas de Gran Canaria, Spain, 22–24 July 2015
Liepa, P.: Filling holes in meshes. In: Proceedings of the Eurographics/ACM SIGGRAPH Symposium on Geometry Processing, pp. 200–205. Granada, Spain, 1–6 Sept 2003
Nooruddin, F.S., Turk, G.: Simplification and repair of polygonal models using volumetric techniques. J. IEEE Trans. Visual. Comput. Graph. 9(2), 191–205 (2003)
Zhao, W., Gao, S., lin, H.: A robust hole-filling algorithm for triangular mesh. J. Visual Comput. 23(12), 987–997 (2007)
George, L.P., Seveno, E.: The advancing-front mesh generation method revisited. J. Numer. Methods Eng. 37(7), 3605–3619 (1994)
Eck, M., DeRose, T.D., Kuchamp, T., Hoope, H., Lounsbery, M., Stuetzle, W.: Multi-resolution analysis of arbitrary meshes. In: Processing of SIGGRAPH, pp.173–182. Los Angeles, CA, USA, 6–11 Aug 1995
Perez, P., Gangnet, P., Blake, A.: Poisson image editing. In: Processing of SIGGRAPH, pp. 313–318. San Diego, California, USA, 27–31 July 2003
Paquet, E., Rioux, M.: Nefertiti: a query by content system for three-dimensional model and image databases management. J. Image Vis. Comput. 17(2), 157–166 (1999)
Shamir, A.: A survey on mesh segmentation techniques. J. Comput. Graph. Forum 27(6), 1539–1556 (2008)
Chen, X., Golovinskiy, A., Funkhouser, T.: A benchmark for 3D mesh segmentation. J. ACM Trans. Graph. 28(3) (2009)
Wang, J., Yu, Z.: Surface feature based mesh segmentation. J. Comput. Graph. 35(3), 661–667 (2011)
Sun, X., Rosin, P., Martin, R., Langbein, F.: Fast and effective feature-preserving mesh denoising. J. IEEE Trans. Visual. Computer Graph. 13(5), 925–938 (2007)
do Carmo, M.: Differential Geometry of Curves and Surfaces. Prentice-Hall (1976)
Besl, P.J., Jain, R.: Segmentation through variable-order surface fitting. J. IEEE Trans. Pattern Anal. Mach. Intell. 10(2), 167–192 (1998)
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Ture Savadkoohi, B., De Amicis, R. (2016). Computer Aided Process as 3D Data Provider in Footwear Industry. In: Pietro, G., Gallo, L., Howlett, R., Jain, L. (eds) Intelligent Interactive Multimedia Systems and Services 2016. Smart Innovation, Systems and Technologies, vol 55. Springer, Cham. https://doi.org/10.1007/978-3-319-39345-2_41
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DOI: https://doi.org/10.1007/978-3-319-39345-2_41
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