Fashion & Textile Research Journal (한국의류산업학회지)

The Society of Fashion and Textile Industry (한국의류산업학회)
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A Case Study on Manufacturing Processes for Virtual Garment Sample

  • Choi, Young Lim (Dept. of Fashion Design/Art & Design Institute, Daegu University)
  • Received : 2017.08.29
  • Accepted : 2017.09.30
  • Published : 2017.10.31
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Abstract

Advances in 3D garment simulation technology contribute greatly to consumers becoming more immersed in movies and games by realistically expressing the garments the characters in the movie or game are wearing. The fashion industry has reached a point where it needs to maximize efficiency in production and distribution to go beyond time and space in order to compete on the global market. The processes of design and product development in the fashion industry require countless hours of work and consume vast resources in terms of materials and energy to repeat sample production and assessment. Therefore, the design and product development tools and techniques must aim to reduce the sample making process. Therefore, this study aims to study a case for comparing the real garment sample making process to the virtual garment sample making process. In this study, we have analysed the differences between the real and virtual garment making processes by choosing designated patterns. As we can see from the study results, the real and virtual garments generally are made through similar processes in manufacturing, while the time consumed for each shows great variation. In real garment making, scissoring and sewing require the greatest number of work hours, whereas in virtual garment making, most of the time was spent in the simulation process.

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References

  1. Baraff, D., & Witkin, A. (1998). Large steps in cloth simulation. Proceedings of SIGGRAPH 98, computer graphics proceedings, 43-54. doi:10.1145/280814.280821. Orlando, FL: ACM New York
  2. Barrie, L. (2016, December 8). CLO Virtual Fashion moves to Europe on 3D design demand. Just-style. Retrieved December 11, 2016, from https://www.just-style.com
  3. Chiricota, Y., Cochaux, O., & Provost, A. (2001). Geometrical modelling of garments. International Journal of Clothing Science and Technology, 13(1), 38-52. doi:10.1108/09556220110384860
  4. Choi, K. J., & Ko, H. S. (2002). Stable but responsive cloth. Proceedings of SIGGRAPH 98, computer graphics proceedings, 604-611. doi:10.1145/566570.566624. Orlando, FL, USA: ACM New York.
  5. Fontana, M., Rizzi, C., & Cugini, U. (2005). 3D virtual apparel design for industrial applications. Computer-Aided Design, 37, 609-622. doi:10.1016/j.cad.2004.09.004
  6. Hahn, F., Thomaszewski, B., Coros, S., Sumner, R., Cole, F., Meyer, M., DeRose, T., & Gross, M. (2014). Subspace Clothing Simulation Using Adaptive Bases. Proceedings of ACM SIGGRAPH, 33(4), 1-9. doi:10.1145/2601097.2601160. Vancouver: ACM New York.
  7. Kim, S., & Park, C. K. (2007). Basic garment pattern generation using geometric modeling method. International Journal of Clothing Science and Technology, 19(1), 7-17. doi:10.1108/09556220710717017
  8. Noel, P. L. (2008). Extensible dress: the future of digital clothing. Clothing & Textiles Research Journal, 26(2), 119-130. doi: 10.1177/0887302X07310078
  9. Volino, P., & Magnenat-Thalmann, N. (2000). Implementing fast cloth simulation with collision response. CGI'00 Proceedings of the International Conference on Computer Graphics, 257-268. Geneva, Switzerland, Switzerland: IEEE Computer Society Washington, DC. doi:10.1109/CGI.2000.852341.
  10. Zhong, Y., & Xu, B. (2009). Three-dimensional garment dressing simulation. Textile Research Journal, 79(9), 792-803. doi:10.1177/0040517508090779