How to cite this paper
Chakraborty, S & Chatterjee, P. (2013). Selection of materials using multi-criteria decision-making methods with minimum data.Decision Science Letters , 2(3), 135-148.
Refrences
Athawale, V.M., & Chakraborty, S. (2012). Material selection using multi-criteria decision-making methods: A comparative study, Proc. of Institution of Mechanical Engineers, Part L, Journal of Materials: Design and Applications, 226, 267-286.
Bahraminasab, M., & Jahan, A. (2011). Material selection for femoral component of total knee replacement using comprehensive VIKOR. Materials & Design, 32, 4471-4477.
Cal??kan, H., Kur?uncu, B., Kurbano?lu, C., & Güven, S.Y. (2013). Material selection for the tool holder working under hard milling conditions using different multi criteria decision making methods. Materials & Design, 45, 473-479.
Cavallini, C., Giorgetti, A., Citti, P., & Nicolaie, F. (2013). Integral aided method for material selection based on quality function deployment and comprehensive VIKOR algorithm. Materials & Design, 47, 27-34.
Chatterjee, P., Athawale, V.M., & Chakraborty, S. (2009). Selection of materials using compromise ranking and outranking methods. Materials & Design, 30, 4043-4053.
Chatterjee, P., Athawale, V.M., & Chakraborty, S. (2011). Materials selection using complex proportional assessment and evaluation of mixed data methods. Materials & Design, 32, 851-860.
Chatterjee, P., & Chakraborty, S. (2012). Material selection using preferential ranking methods. Materials & Design, 35, 384-393.
Chauhan, A., & Vaish, R. (2012). Magnetic material selection using multiple attribute decision making approach. Materials & Design, 36, 1-5.
Edwards, K.L. (2005). Selecting materials for optimum use in engineering components. Materials & Design, 26, 469-473.
Fayazbakhsh, K., Abedian, A., Manshadi, B.D., & Khabbaz, R.S. (2009). Introducing a novel method for materials selection in mechanical design using Z-transformation in statistics for normalization of material properties. Materials & Design, 30, 4396-4404.
Findik, F., & Turan, K. (2012). Materials selection for lighter wagon design with a weighted property index method. Materials & Design, 37, 470-477.
Girubha, R.J., & Vinodh, S. (2012). Application of fuzzy VIKOR and environmental impact analysis for material selection of an automotive component. Materials & Design, 37, 478-486.
Jahan, A., Ismail, M.Y., Sapuan, S.M., & Mustapha, F. (2010). Material screening and choosing methods - A review. Materials & Design, 31, 696-705.
Jahan, A., Mustapha, F., Ismail, M.Y., Sapuan, S.M., & Bahraminasab, M. (2011). A comprehensive VIKOR method for material selection. Materials & Design, 32, 1215-1221.
Jahan, A., Bahraminasab, M., & Edwards, K.L. (2012). A target-based normalization technique for materials selection. Materials & Design, 35, 647-654.
Jee, D-H., & Kang K-J. (2000). A method for optimal material selection aided with decision making theory. Materials & Design, 21, 199-206.
Jiao, Q., Lan, Y., Guan, Z., & Li, Z. (2011). A new material selection approach using PROMETHEE method. Proc. of International Conference Electronic & Mechanical Engineering and Information Technology, 2950-2954.
Karande, P., Gauri, S.K., & Chakraborty, S. (2013). Applications of utility concept and desirability function for materials selection. Materials & Design, 45, 349-358.
Manshadi, B.D., Mahmudi, H., Abedian, A., & Mahmudi, R. (2007). A novel method for materials selection in mechanical design: Combination of non-linear linearization and a modified digital logic method. Materials & Design, 28: 8-15.
Milani, A.S., Shanian, A., Madoliat, R., & Neme, J.A. (2005). The effect of normalization norms in multiple attribute decision making models: A case study in gear material selection. Structural and Multidisciplinary Optimization, 29, 312-318.
Miller, G.A. (1965). The magic number seven plus or minus two. Psychological Review, 63, 81-97.
Olson, D.L. (1996). Decision Aids for Selection Problems. New York: Springer.
Peng, A-H., & Xiao, X-M. (2013). Material selection using PROMETHEE combined with analytic network process under hybrid environment. Materials & Design, 47, 643-652.
Rao, R.V. (2008). A decision making methodology for material selection using an improved compromise ranking method. Materials & Design, 29, 1949-1954.
Rao, R.V., & Davim, J.P. (2008). A decision-making framework model for material selection using a combined multiple attribute decision-making method. International Journal of Advanced Manufacturing Technology, 35, 751-760.
Rao, R.V., & Patel, B.K. (2010). A subjective and objective integrated multiple attribute decision making method for material selection. Materials & Design, 31, 4738-4747.
Rathod, M.K., & Kanzaria, H.V. (2011). A methodological concept for phase change material selection based on multiple criteria decision analysis with and without fuzzy environment. Materials & Design, 32, 3578-3585.
Shanian, A., & Savadogo, O. (2006). TOPSIS multiple-criteria decision support analysis for material selection of metallic bipolar plates for polymer electrolyte fuel cell. Journal of Power Sources, 159: 1095-1104.
Shanian, A., & Savadogo, O. (2006). A material selection model based on the concept of multiple attribute decision making. Materials & Design, 27, 329-337.
Shanian, A., & Savadogo, O. (2006). A non-compensatory compromised solution for material selection of bipolar plates for polymer electrolyte membrane fuel cell (PEMFC) using ELECTRE IV. Electrochimica Acta, 51, 5307-5315.
Thakker, A., Jarvis, J., Buggy, M., & Sahed, A. (2008). A novel approach to materials selection strategy case study: Wave energy extraction impulse turbine blade. Materials & Design, 29, 1973-1980.
Yurdakul, M., & ?ç, Y.T. (2009). Application of correlation test to criteria selection for multi criteria decision making (MCDM) models. International Journal of Advanced Manufacturing Technology, 40, 403-412.
Bahraminasab, M., & Jahan, A. (2011). Material selection for femoral component of total knee replacement using comprehensive VIKOR. Materials & Design, 32, 4471-4477.
Cal??kan, H., Kur?uncu, B., Kurbano?lu, C., & Güven, S.Y. (2013). Material selection for the tool holder working under hard milling conditions using different multi criteria decision making methods. Materials & Design, 45, 473-479.
Cavallini, C., Giorgetti, A., Citti, P., & Nicolaie, F. (2013). Integral aided method for material selection based on quality function deployment and comprehensive VIKOR algorithm. Materials & Design, 47, 27-34.
Chatterjee, P., Athawale, V.M., & Chakraborty, S. (2009). Selection of materials using compromise ranking and outranking methods. Materials & Design, 30, 4043-4053.
Chatterjee, P., Athawale, V.M., & Chakraborty, S. (2011). Materials selection using complex proportional assessment and evaluation of mixed data methods. Materials & Design, 32, 851-860.
Chatterjee, P., & Chakraborty, S. (2012). Material selection using preferential ranking methods. Materials & Design, 35, 384-393.
Chauhan, A., & Vaish, R. (2012). Magnetic material selection using multiple attribute decision making approach. Materials & Design, 36, 1-5.
Edwards, K.L. (2005). Selecting materials for optimum use in engineering components. Materials & Design, 26, 469-473.
Fayazbakhsh, K., Abedian, A., Manshadi, B.D., & Khabbaz, R.S. (2009). Introducing a novel method for materials selection in mechanical design using Z-transformation in statistics for normalization of material properties. Materials & Design, 30, 4396-4404.
Findik, F., & Turan, K. (2012). Materials selection for lighter wagon design with a weighted property index method. Materials & Design, 37, 470-477.
Girubha, R.J., & Vinodh, S. (2012). Application of fuzzy VIKOR and environmental impact analysis for material selection of an automotive component. Materials & Design, 37, 478-486.
Jahan, A., Ismail, M.Y., Sapuan, S.M., & Mustapha, F. (2010). Material screening and choosing methods - A review. Materials & Design, 31, 696-705.
Jahan, A., Mustapha, F., Ismail, M.Y., Sapuan, S.M., & Bahraminasab, M. (2011). A comprehensive VIKOR method for material selection. Materials & Design, 32, 1215-1221.
Jahan, A., Bahraminasab, M., & Edwards, K.L. (2012). A target-based normalization technique for materials selection. Materials & Design, 35, 647-654.
Jee, D-H., & Kang K-J. (2000). A method for optimal material selection aided with decision making theory. Materials & Design, 21, 199-206.
Jiao, Q., Lan, Y., Guan, Z., & Li, Z. (2011). A new material selection approach using PROMETHEE method. Proc. of International Conference Electronic & Mechanical Engineering and Information Technology, 2950-2954.
Karande, P., Gauri, S.K., & Chakraborty, S. (2013). Applications of utility concept and desirability function for materials selection. Materials & Design, 45, 349-358.
Manshadi, B.D., Mahmudi, H., Abedian, A., & Mahmudi, R. (2007). A novel method for materials selection in mechanical design: Combination of non-linear linearization and a modified digital logic method. Materials & Design, 28: 8-15.
Milani, A.S., Shanian, A., Madoliat, R., & Neme, J.A. (2005). The effect of normalization norms in multiple attribute decision making models: A case study in gear material selection. Structural and Multidisciplinary Optimization, 29, 312-318.
Miller, G.A. (1965). The magic number seven plus or minus two. Psychological Review, 63, 81-97.
Olson, D.L. (1996). Decision Aids for Selection Problems. New York: Springer.
Peng, A-H., & Xiao, X-M. (2013). Material selection using PROMETHEE combined with analytic network process under hybrid environment. Materials & Design, 47, 643-652.
Rao, R.V. (2008). A decision making methodology for material selection using an improved compromise ranking method. Materials & Design, 29, 1949-1954.
Rao, R.V., & Davim, J.P. (2008). A decision-making framework model for material selection using a combined multiple attribute decision-making method. International Journal of Advanced Manufacturing Technology, 35, 751-760.
Rao, R.V., & Patel, B.K. (2010). A subjective and objective integrated multiple attribute decision making method for material selection. Materials & Design, 31, 4738-4747.
Rathod, M.K., & Kanzaria, H.V. (2011). A methodological concept for phase change material selection based on multiple criteria decision analysis with and without fuzzy environment. Materials & Design, 32, 3578-3585.
Shanian, A., & Savadogo, O. (2006). TOPSIS multiple-criteria decision support analysis for material selection of metallic bipolar plates for polymer electrolyte fuel cell. Journal of Power Sources, 159: 1095-1104.
Shanian, A., & Savadogo, O. (2006). A material selection model based on the concept of multiple attribute decision making. Materials & Design, 27, 329-337.
Shanian, A., & Savadogo, O. (2006). A non-compensatory compromised solution for material selection of bipolar plates for polymer electrolyte membrane fuel cell (PEMFC) using ELECTRE IV. Electrochimica Acta, 51, 5307-5315.
Thakker, A., Jarvis, J., Buggy, M., & Sahed, A. (2008). A novel approach to materials selection strategy case study: Wave energy extraction impulse turbine blade. Materials & Design, 29, 1973-1980.
Yurdakul, M., & ?ç, Y.T. (2009). Application of correlation test to criteria selection for multi criteria decision making (MCDM) models. International Journal of Advanced Manufacturing Technology, 40, 403-412.