Abstract
An interactive clothing design and a personalized virtual display with user’s own face are presented in this paper to meet the requirement of personalized clothing customization. A customer interactive clothing design approach based on genetic engineering ideas is analyzed by taking suit as an example. Thus, customers could rearrange the clothing style elements, chose available color, fabric and come up with their own personalized suit style. A web 3D customization prototype system of personalized clothing is developed based on the Unity3D and VR technology. The layout of the structure and functions combined with the flow of the system are given. Practical issues such as 3D face scanning, suit style design, fabric selection, and accessory choices are addressed also. Tests to the prototype system indicate that it could show realistic clothing and fabric effect and offer effective visual and customization experience to users.
Similar content being viewed by others
References
Ai QS, Wang Y (2012) Review of contemporary product gene research in design and modeling areas. J Adv Mech Des Syst Manuf 6(7):1234–1249
Ai QS, Wang Y, Liu Q (2013) An intelligent method of product scheme design based on product gene. Adv Mech Eng 5:489257
Balasubramanian M, Schwartz EL (2002) The isomap algorithm and topological stability. Science 295(5552):7
Begole B, Matsumoto T, Zhang W, et al. (2009) A 3D virtual show room for online apparel retail shop. In: Proc. 13th international conference on human-computer interaction. Part IV: Interacting in Various Application Domains, pp 448–457
Blanz V, Vetter T (1999). A morphable model for the synthesis of 3D faces. Conference on Computer Graphics and Interactive Techniques(pp.187–194). ACM Press/Addison-Wesley Publishing Co
Cordier F, Seo H, Magnenat-Thalmann N (2003) Made-to-measure Technologies for an Online Clothing Store. IEEE Comput Graph Appl 23(1):38–48
DNA ,https://en.wikipedia.org/wiki/DNA. Accessed 27 Sept 2017
GRAFIS CAD-software provided by the GRAFIS software - Dr. K Friedrich GbR http://www.grafis.com/. Accessed 16 Oct 2017
Grupp M, Kopp P, Huber P, Rätsch M (2016) A 3D Face Modelling Approach for Pose-Invariant Face Recognition in a Human-Robot Environment. arXiv preprint arXiv:1606.00474
Hangyue C, Shijian L (2008) Product visual image design based on product family DNA. In Computer-Aided Industrial Design and Conceptual Design, 2008. CAID/CD 2008. 9th International Conference on. IEEE, pp 783–787
http://qqapp.qq.com/app/100624523.html. Accessed 28 Jan 2017
https://www.taobao.com. Accessed 27 Jan 2017
Huber P, Feng ZH, Christmas W et al. (2015) Fitting 3d morphable models using local features. 1195–1199
Huber P, Hu G, Tena R, et al., (2016) A multiresolution 3D morphable face model and fitting framework. In: Proceedings of the 11th international joint conference on computer vision, Imaging and Computer Graphics Theory and Applications
Huber P, Kopp P, Christmas W, Rätsch M, Kittler J (2017) Real-time 3D face fitting and texture fusion on in-the-wild videos. IEEE Signal Process Let 24(4):437–441
Jevšnik S, Stjepanovič Z, Rudolf A (2017) 3d virtual prototyping of garments: approaches, developments and challenges. J Fiber Bioeng Inf 10(1):51–63
Jiang X, Hu X, He L (2010) Virtual display system of Virtools in e-commerce. In Advanced Computer Control (ICACC), 2010 2nd International Conference on, Vol. 1. IEEE, pp 493–496
Lafon R (2004) 3DS MAX 7. CADalyst 12:30–33
Li YS, Meng L, Li L (2011) On Forecasting of Production Cycle of Make-To-Order Products. In Information Management, Innovation Management and Industrial Engineering (ICIII), 2011 International Conference on, Vol 3. IEEE, pp 3–6
Liu S, Tang Y, Luo S (2009) A study of product family design DNA based on product style. In Computer-Aided Industrial Design and Conceptual Design, 2009. CAID and CD 2009. IEEE 10th International Conference on. IEEE, pp 377–382
Marcolin F, Vezzetti E (2016) Novel descriptors for geometrical 3d face analysis. Multimed Tools Appl 76:1–30
Milborrow S, Bishop T, Nicolls F (2013) Multiview active shape models with sift descriptors for the 300-w face landmark challenge. In: Proceedings of the IEEE International Conference on Computer Vision Workshops, pp 378–385
Nair P, Cavallaro A (2009) 3-D face detection, landmark localization, and registration using a point distribution model. IEEE Trans Multimed 11(4):611–623
Sabina O, Elena S, Emilia F, Adrian S (2014) Virtual fitting–innovative technology for customize clothing design. Proc Eng 69:555–564
Tudjarov B, Bachvarov A, Boyadjiev I (2008) Web virtual reality for product customization. In: Proceedings of the 3rd international conference on mass customization and personalization in Central Europe (MCP-CE 2008), Novi Sad, Serbia, pp 7–13
Vidya System provided by the Assyst GmbH (Human Solutions Group). http://www.human-solutions.com/group/front_content.php?idcat=214. Accessed 16 Oct 2017
Violante MG, Vezzetti E (2014) Implementing a new approach for the design of an e-learning platform in engineering education. Comput Appl Eng Educ 22(4):708–727
Xiaogang L (2008) Elements of clothing design. J Donghua Univ (Natural Science Edition) 4:23–26
Xiao-Ling LI, Chang-De LU (2007) Research on interactive virtual presentation technology based on web. Comput Eng Appl 43(3):90–92
Xie X, Livermore C (2016) A pivot-hinged, multilayer SU-8 micro motion amplifier assembled by a self-aligned approach. IEEE, International Conference on MICRO Electro Mechanical Systems. IEEE, pp 75–78
Xie X, Livermore C (2017). Passively self-aligned assembly of compact barrel hinges for high-performance, out-of-plane mems actuators. In: Micro Electro Mechanical Systems (MEMS), 2017 I.E. 30th International Conference on. IEEE, pp 813–816
Xie X, Zaitsev Y, Velásquez-García LF, Teller SJ, Livermore C (2014) Scalable, MEMS-enabled, vibrational tactile actuators for high resolution tactile displays. J Micromech Microeng 24(12):125014
Xin X, Yuri Z, Luis F (2014) Scalable, MEMS-enabled, vibrational tactile actuators for high resolution tactile displays. J Micromech Microeng (JMM) 24(12):125014
Zeng Y, Wang C, Gu X, Samaras D, Paragios N (2016) Higher-order graph principles towards non-rigid surface registration. IEEE Trans Pattern Anal Mach Intell 38(12):2416–2429
Zhang XF, Huang RQ (2014) Virtual display design and evaluation of clothing: a design process support system. Int J Technol Des Educ 24(2):223–240
Zhu S (2004) Technique of fabric simulation and development of cad system. Cotton Textile Technology
Zhu S, Luo S (2007) A preliminary study on product family DNA in industrial design. In: Computer Supported Cooperative Work in Design, 2007. CSCWD 2007. 11th International Conference on. IEEE, pp 337–342
Author information
Authors and Affiliations
Corresponding author
Electronic supplementary material
ESM 1
(AVI 106726 kb)
Rights and permissions
About this article
Cite this article
Zhu, Xj., Lu, H. & Rätsch, M. An interactive clothing design and personalized virtual display system. Multimed Tools Appl 77, 27163–27179 (2018). https://doi.org/10.1007/s11042-018-5912-x
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11042-018-5912-x