286                                     Anthropometry, Apparel Sizing and Design

            The presented concept can greatly contribute to accelerating the process of devel-
         oping and testing new model prototypes, increasing the quality of finished products,
         and reducing the cost of real prototype production processes. Scientific research in this
         area is the subject of research conducted at the Department of Clothing Technology at
         the Faculty of Textile Technology of the University of Zagreb. This work was
         supported by the Croatian Science Foundation under the project number 3011: Appli-
         cation of mathematical modelling and intelligent algorithms in clothing construction.


         References

               ¸
         Braganca, S., et al., 2016. Current state of the art and enduring issues in anthropometric data
             collection. Dyna Dyna Rev. Fac. Nac. Minas 83(197). https://doi.org/10.15446/dyna.
             v83n197.57586.
         Chun, J., Oh, S., 2004. 3D body scanning posture to collect anthropometric data for garment
             making. J. Asian Reg. Assoc. Home Econ. 11 (4), 301–307.
         D’Apuzzo, N., 2009. Recent advances in 3D full body scanning with applications to fashion and
             apparel. In: 9th Conference on Optical 3D Measurement Techniques, Vienna, Austria.
         D’Apuzzo, N., 2009. Recent advances in 3D full body scanning with applications to fashion and
             apparel. In: 9th Conference on Optical 3-D Measurement Techniques, Vienna, Austria.
         Diving Unlimited International Inc, 2013. Dui Drysuit Owner’s Manual, EN 14225-2:2005,San
             Diego, CA 92102-2499, USA. .
         Fan, J., Yu, W., Hunter, L., 2004. Clothing Appearance and Fit: Science and Technology.
             Woodhead Publishing Limited and The Textile Institute, Cambridge.
         Fang, J., Ding, Y., Huang, S., 2008. Expert-based customized pattern-making automation. Part
             II. Dart design. Int. J. Cloth. Sci. Technol. 20 (1), 41–56.
         Gers ˇak, J., 2001. Objektivno vrednovanje plos ˇnih tekstilija i odje  ce. Sveu  cilis ˇte u Zagrebu,
             Tekstilno—tehnolos ˇki fakultet, Zagreb.
         Gers ˇak, J., Mar  ci  c, M., 2013. The complex design concept for functional protective clothing.
             Tekstil 62, 38–44.
         Gill, S., Heyes, S., 2012. Lower body functional ease requirements in the garment pattern. Int. J.
             Fash. Des. Technol. Educ 5, 13–23.
         Gupta, D., 2011. Design and engineering of functional clothing. Indian J. Fibre Text. Res.
             36, 327–335.
         Igarashi, T., Hughes, J.F., 2002. Clothing manipulation. In: 15th Annual Symposium on User
             Interface Software and Technology, ACM UIST’02, pp. 91–100.
         ISO 20685:2010: 3-D Scanning Methodologies for Internationally Compatible Anthropometric
             Databases (n.d.).
         Lee, H., Hong, K., Lee, Y., 2013. Ergonomic mapping of skin deformation in dynamic postures
             to provide fundamental data for functional design lines of outdoor pants. Fibers Polym.
             14, 2197–2201.
         Magnenat-Thalmann, N., Volino, P., 2005. From early draping to haute couture models: 20 years
             of research. Vis. Comput. 21 (8), 506–519.
         Mahnic Naglic, M., Petrak, S., 2017. A method for body posture classification of three-
             dimensional body models in the sagittal plane. Text. Res. J. 1–17. https://doi.org/
             10.1177/0040517517741155 (Online first).