To develop smart sportswear capable of measuring biometric data, we created a close-fitting pattern using two- and three-dimensional (2D and 3D, respectively) methods. After 3D virtual fitting, the tightness of each pattern was evaluated using image processing of contact points, mesh deviation, and ...
To develop smart sportswear capable of measuring biometric data, we created a close-fitting pattern using two- and three-dimensional (2D and 3D, respectively) methods. After 3D virtual fitting, the tightness of each pattern was evaluated using image processing of contact points, mesh deviation, and cross-sectional shapes. In contact-point analysis, the 3D pattern showed high rates of contact with the body (84.6% and 93.1% for shirts and pants, respectively). Compared with the 2D pattern, the 3D pattern demonstrated closer contact at the lower chest, upper arm, and thigh regions, where electrocardiography and electromyography were primarily carried out. The overall average gap was also lower in the 3D pattern (5.27 and 4.66 mm in shirts and pants, respectively). In the underbust, waist, thigh circumference, and mid-thigh circumference, the cross-section distance between clothing and body was showed a statistically significant difference and evenly distributed in the 3D pattern, exhibiting more closeness. The tightness and fit of the 3D smart sportswear sensor pattern were successfully evaluated. We believe that this study is critical, as it facilitates the comparison of different patterns through visualization and digitization through 3D virtual fitting.
To develop smart sportswear capable of measuring biometric data, we created a close-fitting pattern using two- and three-dimensional (2D and 3D, respectively) methods. After 3D virtual fitting, the tightness of each pattern was evaluated using image processing of contact points, mesh deviation, and cross-sectional shapes. In contact-point analysis, the 3D pattern showed high rates of contact with the body (84.6% and 93.1% for shirts and pants, respectively). Compared with the 2D pattern, the 3D pattern demonstrated closer contact at the lower chest, upper arm, and thigh regions, where electrocardiography and electromyography were primarily carried out. The overall average gap was also lower in the 3D pattern (5.27 and 4.66 mm in shirts and pants, respectively). In the underbust, waist, thigh circumference, and mid-thigh circumference, the cross-section distance between clothing and body was showed a statistically significant difference and evenly distributed in the 3D pattern, exhibiting more closeness. The tightness and fit of the 3D smart sportswear sensor pattern were successfully evaluated. We believe that this study is critical, as it facilitates the comparison of different patterns through visualization and digitization through 3D virtual fitting.
Baek, Y. J., & Choi, J. W. (2008). Determination of the garment?pressure level using the elastic bands by human body parts.?Journal of the Korean Society of Clothing and Textiles, 32(10), 1651-1658. doi:10.5850/JKSCT.2008.32.10.1651
Choi, J.-H. (2011). A study about reduction rate of wetsuit patterns for men in their 30's. Journal of the Korean Society of?Clothing and Textiles, 35(9), 1039-1048. doi:10.5850/JKSCT.2011.35.9.1039
Choi, J., & Hong, K. (2015). 3D skin length deformation of?lower body during knee joint flexion for the practical application of functional sportswear. Applied Ergonomics, 48,?186-201. doi:10.1016/j.apergo.2014.11.016
Choi, Y. L., & Nam, Y. J. (2009). The qualitative study on the?evaluation and the application of 3D scan and virtual try-on?technology. Journal of the Korean Society for Clothing Industry, 11(3), 437-444.
Do, W.-H. (2012). A study on the fit preferences of the tailored?jacket for women using 3D clothes modeling system. Journal of the Korean Society of Clothing and Textiles, 36(9),?940-951. doi:10.5850/JKSCT.2012.36.9.940
Jeong, Y. (2013). 3D virtual clothing menswear pattern design?I. Seoul: Ybook.
Jeong, Y. (2014). 3D virtual clothing menswear pattern design?II. Seoul: Ybook.
Jeong, Y. (2016). Development of ergonomic pattern for motorcycle pants using 3D virtual clothing. Korean Journal of?Human Ecology, 25(2), 207-225. doi:10.5934/kjhe.2016.25.2.207
Jeong, Y., Hong, K., & Kim, S.-J. (2006). 3D pattern construction and its application to tight-fitting garments for comfortable pressure sensation. Fibers and Polymers, 7(2), 195-202.
Jeong, Y., & Hong, K. (2006). Development of 2D tight-fitting?pattern from 3D scan data. Journal of the Korean Society of?Clothing and Textiles, 30(1), 157-166.
Kim, M. (2020). A study on reproductions of North American?smocking design using a 3D virtual clothing system. Journal of Fashion Business, 24(5), 106-124. doi:10.12940/jfb.2020.24.5.106
Kim, S. (2019). Development of sports brassiere pattern using?3D shaping technology. Fashion & Textile Research Journal, 21(4), 480-487. doi:10.5805/SFTI.2019.21.4.480
Kim, S., Hong, K., & Lee, H. (2019). Evaluation of efficacy of?body shaper for senior women using 3D scanned data. Fashion & Textile Research Journal, 21(2), 220-230. doi:10.5805/SFTI.2019.21.2.220
Kim, S., Lee, H., Choi, J., & Hong, K. (2017). Subjective wear?test and fit of women's sports underwear made of cool-touch?fabric. The Korean Journal of Community Living Science,?28(4), 505-514. doi:10.7856/kjcls.2017.28.4.505
Kim, T.-G., Park, S., Park, J.-W., Suh, C., & Choi, S.-A. (2012).?Technical design of tight upper sportswear based on 3D?scanning technology and stretch property of knitted fabric.?Journal of the Korean Society for Clothing Industry, 14(2),?277-285. doi:10.5805/KSCI.2012.14.2.277
Korean Agency for Technology and Standards. (n.d.-a). 인체?항목 검색 > 측정 항목 검색 [Search for human body items >?Search metrics]. Size Korea. Retrieved from https://sizekorea.kr/human-meas-search/human-data-search/meas-item
Korean Agency for Technology and Standards. (n.d.-b). 3차원?인체 형상 [3D human body shape]. Size Korea. Retrieved?from https://sizekorea.kr/human-meas-search/3d-human-shape/intro
Kwon, M., Choi, S., & Kim, J. (2021). Investigation of the body?distribution of load pressure and virtual wear design according to the corset type harness. Journal of the Korea Fashion & Costume Design Association, 23(3), 1-10. doi:10.30751/kfcda.2021.23.3.1
Lee, H. (2016). Methods to determine the size of pant patterns?with curved design lines and their three dimensional construction using 3D virtual fitting. Journal of Fashion Business, 20(4), 153-171. doi:10.12940/jfb.2016.20.4.153
Lee, H., & Choi, J. (2021). Study on the reconstruction of celebrities' clothing using a 3D virtual clothing system - Featuring Grace Kelly's ladylike styled clothing -. Journal of the?Korean Society of Costume, 71(5), 38-56. doi:10.7233/jksc.2021.71.5.038
Lee, H., & Hong, K. (2005). Development of a fitted bodice?pattern using a 3D replica of women's upper body. Journal?of the Korean Society of Clothing and Textiles, 29(7), 1008-1017.
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 and?Polymers, 14(12), 2197-2201. doi:10.1007/s12221-013-2197-6
Lee, O., Hong, K., & Lee, Y. (2021). Development of the fundamental methodology of lower cup pattern depending on?3D shape analysis of breast. Journal of the Korean Society?of Clothing and Textiles, 45(1), 94-105. doi:10.5850/JKSCT.2021.45.1.94
Lee, O., Lee, H., Lee, Y., & Kim, S. (2021). Amount of change?in length and clothing pressure over the pressure measurement area depending on the direction of the fabric for the?development of compression garment. Korean Journal of?Human Ecology, 30(3), 501-511. doi:10.5934/kjhe.2021.30.3.501
Lim, J. (2010). A development of the torso pattern for obese?middle-aged women from 3D virtual garment simulation.?Journal of the Korean Society for Clothing Industry, 12(1),?86-93. doi:10.5805/KSCI.2010.12.1.086
Marutani, Y., Konda, S., Ogasawara, I., Yamasaki, K., Yokoyama, T., Maeshima, E., & Nakata, K. (2022). An experimental feasibility study evaluating the adequacy of a sportswear-type wearable for recording exercise intensity. Sensors, 22(7):2577. doi:10.3390/s22072577
Park, G. A. (2020). The evaluation of the work motion suitability of men's coverall type painting work clothes using?3D virtual clothing simulation. Journal of Fashion Business, 24(4), 63-84. doi:10.12940/jfb.2020.24.4.63
Park, J.-H., & Kim, J.-Y. (2019). A study on the development of?sleep monitoring smart wear based on fiber sensor for the?management of sleep apnea. Science of Emotion and Sensibility, 22(1), 89-100. doi:10.14695/KJSOS.2018.22.1.89
Park, S., & Kim, H. (2010). A study on setting darts and split?lines of upper bodice pattern on 3D parametric model dressed with tight-fit garment. Journal of the Korean Society for?Clothing Industry, 12(4), 467-476. doi:10.5805/KSCI.2010.12.4.467
Park, S., & Lee, Y. (2022). Comparison of slim appearance for?2D image and 3D virtual clothing images based on stripe?arrangement. Journal of the Korean Society of Clothing and?Textiles, 46(2), 321-330. doi:10.5850/JKSCT.2022.46.2.321
Patel, S., Park, H., Bonato, P., Chan, L., & Rodgers, M. (2012).?A review of wearable sensors and systems with application?in rehabilitation. Journal of NeuroEngineering and Rehabilitation, 9:21. doi:10.1186/1743-0003-9-21
Shin, J.-H., & Son, H.-S. (2013). A study on the development of?basic bodice block pattern by women's body type from 3D?virtual clothing system - Focusing on early 20's women -.?Journal of the Korea Fashion & Costume Design Association, 15(2), 1-13.
Sohn, B. (2008). The visual illusion using the adequate ease?distribution of jacket pattern for the middle aged women of?obese figure. Korean Journal of Human Ecology, 17(3), 469-483. doi:10.5934/KJHE.2008.17.3.469
Wu, Y., & Hong, K. (2012). Methods of merging a 3D replica?and ease distribution for woman's pant patterns. Journal of?the Korean Society of Clothing and Textiles, 36(4), 443-455. doi:10.5850/JKSCT.2012.36.4.443
Yoon, M. K., & Nam, Y. J. (2016). Women's pant pattern design?according to the style using 3D body scan data. Journal of?the Korean Society of Clothing and Textiles, 40(1), 97-113.?doi:10.5850/jksct.2016.40.1.97
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