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Visual-Simulation-Based Personalized Garment Block Design Method for Physically Disabled People with Scoliosis (PDPS)

Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
This research presented a novel method using 3D simulation methods to design customized garments for physically disabled people with scoliosis (PDPS). The proposed method is based on the virtual human model created from 3D scanning, permitting to simulate the consumer’s morphological shape with atypical physical deformations. Next, customized 2D and 3D virtual garment prototyping tools will be used to create products through interactions. The proposed 3D garment design method is based on the concept of knowledge-based design, using the design knowledge and process already applied to normal body shapes successfully. The characters of the PDPS and the relationship between human body and garment are considered in the prototyping process. As a visualized collaborative design process, the communication between designer and consumer is ensured, permitting to adapt the finished product to disabled people afflicted with severe scoliosis.
Rocznik
Strony
35--45
Opis fizyczny
Bibliogr. 27 poz.
Twórcy
autor
  • College of Textile and Clothing Engineering, Soochow University, Suzhou 215021, China
  • GEMTEX, ENSAIT, 2 allée Louise et Victor Champier, 59056 Roubaix Cedex 1, France
  • Technical University of Iasi, Dimitrie Mangeron Bd., 53, Iasi -700050, Romania
autor
  • GEMTEX, ENSAIT, 2 allée Louise et Victor Champier, 59056 Roubaix Cedex 1, France
autor
  • GEMTEX, ENSAIT, 2 allée Louise et Victor Champier, 59056 Roubaix Cedex 1, France
autor
  • GEMTEX, ENSAIT, 2 allée Louise et Victor Champier, 59056 Roubaix Cedex 1, France
autor
  • Technical University of Iasi, Dimitrie Mangeron Bd., 53, Iasi -700050, Romania
autor
  • College of Textile and Clothing Engineering, Soochow University, Suzhou 215021, China
Bibliografia
  • [1] Subramanyam R, Schaffzin J, Cudilo EM, Rao MB and Varughese AM. Systematic review of risk factors for surgical site infection in pediatric scoliosis surgery. Spine J. 2015; 15: 1422-31.
  • [2] Hong Y, Zeng X, Bruniaux P and Liu K. Interactive virtual try-on based three-dimensional garment block design for disabled people of scoliosis type. Textile Research Journal. 2016: 0040517516651105.
  • [3] Y. HONG PB, X. ZENG1, K. LIU, M.DONG. Virtual Reality Based Collaborative Design Method for Designing Customized Garment of Disabled People with Scoliosis. International Journal of Clothing Science and Technology. 2017; 29.
  • [4] Hong Y, Curteza A, Zeng X, Bruniaux P and Chen Y. Sensory evaluation based fuzzy AHP approach for material selection in customized garment design and development process. Book of Abstracts. Iasi: IOP Publishing, 2016, p. 1-8.
  • [5] Luo ZG and Yuen MMF. Reactive 2D/3D garment pattern design modification. Computer-Aided Design. 2005; 37: 623-30.
  • [6] Liu Y-J, Zhang D-L and Yuen MM-F. A survey on CAD methods in 3D garment design. Computers in Industry. 2010; 61: 576-93.
  • [7] HONG Y, ZENG X and BRUNIAUX P. SELECTION AND APPLICATION OF KEY PERFORMANCE INDICATORS FOR DESIGN AND PRODUCTION PROCESS. Uncertainty Modelling in Knowledge Engineering and Decision Making: Proceedings of the 12th International FLINS Conference. Roubaix: World Scientific, 2016, p. 1008-14.
  • [8] Sayem ASM, Kennon R and Clarke N. 3D CAD systems for the clothing industry. International Journal of Fashion Design, Technology and Education. 2010; 3: 45-53.
  • [9] Sayem ASM, Kennon R and Clarke N. Resizable trouser template for virtual design and pattern flattening. International Journal of Fashion Design, Technology and Education. 2012; 5: 55-65.
  • [10] Zhang D, Wang J and Yang Y. Design 3D garments for scanned human bodies. Journal of Mechanical Science and Technology. 2014; 28: 2479-87.
  • [11] Thomassey S and Bruniaux P. A template of ease allowance for garments based on a 3D reverse methodology. International Journal of Industrial Ergonomics. 2013; 43: 406-16.
  • [12] Wang J, Lu G, Li W, Chen L and Sakaguti Y. Interactive 3D garment design with constrained contour curves and style curves. Computer-Aided Design. 2009; 41: 614-25.
  • [13] Wang CCL, Wang Y and Yuen MMF. Design automation for customized apparel products. Computer-Aided Design. 2005; 37: 675-91.
  • [14] Volino P, Cordier F and Magnenat-Thalmann N. From early virtual garment simulation to interactive fashion design. Computer-Aided Design. 2005; 37: 593-608.
  • [15] Goldstein Y, Robinet P, Kartsounis G-A, et al. Virtual prototyping: from concept to 3D design and prototyping in hours. Transforming Clothing Production into a Demand-Driven, Knowledge-Based, High-Tech Industry. Springer, 2009, p. 95-139.
  • [16] WOOD F, Archibald L and Ewing W. THE LINRA SUNRAY CREASE-RECOVERY TEST. Journal of the Textile Institute Proceedings. 1962; 53: P135-P42.
  • [17] Stjepanovic Z. Computer-aided processes in garment production: features of CAD/CAM hardware. International Journal of Clothing Science and Technology. 1995; 7: 81-8.
  • [18] Shin K. Patternmaking for the underwired bra: New directions. Journal of the Textile Institute. 2007; 98: 301-18.
  • [19] Huang H, Mok P, Kwok Y and Au J. Block pattern generation: From parameterizing human bodies to fit feature-aligned and flattenable 3D garments. Computers in Industry. 2012; 63: 680-91.
  • [20] Hinds B, McCartney J and Woods G. Pattern development for 3D surfaces. Computer-Aided Design. 1991; 23: 583-92.
  • [21] Efrat S. The development of a method for generating patterns for garments that conform to the shape of the human body. De Montfort University, 1982.
  • [22] Meng Y, Mok PY and Jin X. Computer aided clothing pattern design with 3D editing and pattern alteration. Computer-Aided Design. 2012; 44: 721-34.
  • [23] Hsiao S-W and Chen R-Q. A study of surface reconstruction for 3D mannequins based on feature curves. Computer-Aided Design. 2013; 45: 1426-41.
  • [24] Jevsnik S, Pilar T, Stjepanovic Z and Rudolf A. Virtual prototyping of garments and their fit to the body. DAAAM International Scientific Book. 2012: 601-19.
  • [25] Fontana M, Rizzi C and Cugini U. 3D virtual apparel design for industrial applications. Computer-Aided Design. 2005; 37: 609-22.
  • [26] HONG Y, ZENG X and BRUNIAUX P. KNOWLEDGE ACQUISITION AND MODELING OF GARMENT PRODUCT DEVELOPMENT. Uncertainty Modelling in Knowledge Engineering and Decision Making: Proceedings of the 12th International FLINS Conference (FLINS 2016). Roubaix: World Scientific, 2016, p. 438-44.
  • [27] Moon KK-L, Yi CY and Ngai EWT. An instrument for measuring supply chain flexibility for the textile and clothing companies. European Journal of Operational Research. 2012; 222: 191-203.
Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-8e888bc3-39cc-4170-9a86-3f2e39f451da
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