Page 91 - Anthropometry, Apparel Sizing and Design

P. 91

120 Anthropometry, Apparel Sizing and Design

Hsu, H.C., Lin, H.F., Wang, M.J., 2006. Development female size charts for facilitating garment
production by using data mining. J. Chin. Inst. Ind. Eng. 24, 245–251.
Hsu, H.C., Lin, H.F., Wang, M.J., 2007. Developing female size charts for facilitating garment
production by using data mining. J. Chin. Inst. Ind. Eng. 24, 245–251.
Hsu, C.H., Tsai, C.Y., Lee, T.Y., 2010. Neural network to develop sizing systems for production
and logistics via technology innovation in Taiwan. In: New Aspects of Applied Informat-
ics, Biomedical Electronics & Informatics and Communications. ISBN 978-960-474-216-
5, pp. 421–424.
Hutcheson, G.D., Sofroniou, N., 1999. The Multivariate Social Scientist: Introductory Statistics
Using Generalized Linear Models. Sage, Thousand Oaks, CA.
James, R., Stone, P., 1984. Children’s Wear Sizing Survey. Clothing and Allied Products Indus-
trial Training Board, Leeds, UK.
Kaiser, S.K., 1997. The Social Psychology of Clothing: Symbolic Appearance in Context, sec-
ond ed. Fairchild Publications, New York, pp. 108–109.
Kim, N., Song, H.K., Kim, S., Do, W., 2018. An effective research method to predict human
body type using an artificial neural network and a discriminant analysis. Fibers Polym.
19 (8), 1781–1789.
LaBat, K.L., 1987. Consumer Satisfaction/Dissatisfaction with the Fit of Ready-to-Wear Cloth-
ing. Unpublished doctoral thesis, University of Minnesota.
Lin, H.F., Hsu, C.H., Wang, M.J., Lin, Y.C., 2008. An application of data mining technique in
developing sizing system for army soldiers in Taiwan. WSEAS Trans. Comput.
7, 245–252.
Makhanya, P.B., de Klerk, H.M., Adamski, K., Mastamet, A.M., 2014. Ethnicity, body shape
differences and female consumer’s apparel fit problems. Int. J. Consum. Stud. 38 (2),
183–191.
Manuel, M.B., Connell, L.J., Presley, A.B., 2010. Body shape and fit preference in body
cathexis and clothing benefits sought for professional African-American women. Int. J.
Fash. Des. Technol. Educ. 3 (1), 25–32.
McCulloch, C.E., Paal, B., Ashdown, S.P., 1998. An optimization approach to apparel sizing.
J. Oper. Res. Soc. 49, 492–499.
Naveed, T., Zhong, Y., Hussain, A., Babar, A.A., Naeem, A., Iqbal, A., Saleemi, S., 2018.
Female body shape classifications and their significant impact on fabric utilization. Fibers
Polym. 19 (12), 2642–2656.
Ng, R., Ashdown, S.P., Chan, A., 2007. Intelligent size table generation. In: Proceedings of the
Asian Textile Conference (ATC), 9th Asian Textile Conference, Taiwan.
O’Brien, R., Shelton, W.C., 1941. Body measurements of American boys and girls for garment
and pattern construction. In: US Department of Agriculture Miscellaneous Publication
366, M. P. 454. US Department of Agriculture, Washington, DC, p. 141.
Otieno, R., Fairhurst, C., 2000. The development of new clothing size charts for female Kenyan
children. Part I: using anthropometric data to create size charts. J. Text. Inst. 91, 143–152.
Otieno, A.O., Mehtre, A., Mekonnen, H., Lema, O., Fera, O., Gebeyehu, S., 2016. Developing
standard size charts for Ethiopian men between the ages of 18-26 through anthropometric
survey. J. Text. Apparel Technol. Manag. 10 (1), 1–10.
Pallant, J., 2001. SPSS Survival Manual. Open University, Maidenhead.
Pei, J., Park, H., Ashdown, S.P., Vuruskan, A., 2017. A sizing improvement methodology based
on adjustment of interior accommodation rates across measurement categories within a
size chart. Int. J. Cloth. Sci. Technol. 29 (5), 716–731.
Raykov, T., Marcoulides, G.A., 2008. An Introduction to Applied Multivariate Analysis.
Routledge.

86 87 88 89 90 91 92 93 94 95 96