How to cite this paper
Delgoshaei, A., Delgoshaei, A & Ali, A. (2019). Review evolution of cellular manufacturing system’s approaches: Human resource planning method.Journal of Project Management, 4(1), 31-42.
Refrences
Aryanezhad, M., Deljoo, V., & Mirzapour Al-e-hashem, S. (2009). Dynamic cell formation and the worker assignment problem: a new model. The International Journal of Advanced Manufacturing Technology, 41(3-4), 329-342.
Askin, R., & Huang, Y. (1997). Employee training and assignment for facility reconfiguration. Proceedings of the sixth IERC, Miami, FL, 426-431.
Askin, R., & Huang, Y. (2001). Forming effective worker teams for cellular manufacturing. International Journal of Production Research, 39(11), 2431-2451.
Bartholdi, J. J., & Eisenstein, D. D. (1996). A production line that balances itself. Operations Research, 44(1), 21-34.
Black, J., & Schroer, B. J. (1993). Simulation of an apparel assembly cell with walking workers and decouplers. Journal of Manufacturing Systems, 12(2), 170-180.
Cesaní, V. I., & Steudel, H. J. (2005). A study of labor assignment flexibility in cellular manufacturing systems. Computers & industrial engineering, 48(3), 571-591.
Chakravorty, S. S., & Hales, D. N. (2004). Implications of cell design implementation: A case study and analysis. European Journal of Operational Research, 152(3), 602-614.
Chakravorty, S. S., & Hales, D. N. (2008). The evolution of manufacturing cells: An action research study. European Journal of Operational Research, 188(1), 153-168.
Ertay, T., & Ruan, D. (2005). Data envelopment analysis based decision model for optimal operator allocation in CMS. European Journal of Operational Research, 164(3), 800-810.
Fitzpatrick, E. L., & Askin, R. G. (2005). Forming effective worker teams with multi-functional skill requirements. Computers & industrial engineering, 48(3), 593-608.
Gel, E., Hopp, W., & Van Oyen, M. (2000). Workforce agility in systems with hierarchical cross-training. Retrieved from
Hamedi, M., Esmaeilian, G., Ismail, N., & Ariffin, M. (2012). Capability-based virtual cellular manufacturing systems formation in dual-resource constrained settings using Tabu Search. Computers & Industrial Engineering, 62(4), 953-971.
Heady, R. B. (1997). Forming minimum-cost machine cells with exceptional parts using zero-one integer programming. Journal of Manufacturing Systems, 16(2), 79-90.
Hyer, N. L., Brown, K. A., & Zimmerman, S. (1999). A socio-technical systems approach to cell design: case study and analysis. Journal of Operations Management, 17(2), 179-203.
Jensen, J. B. (2000). The impact of resource flexibility and staffing decisions on cellular and departmental shop performance. European Journal of Operational Research, 127(2), 279-296.
Kher, H. V. (2000a). Examination of flexibility acquisition policies in dual resource constrained job shops with simultaneous worker learning and forgetting effects. Journal of the Operational Research Society, 51(5), 592-601.
Kher, H. V. (2000b). Examination of flexibility acquisition policies in dual resource constrained job shops with simultaneous worker learning and forgetting effects. Journal of the Operational Research Society, 592-601.
Kher, H. V., Malhotra, M. K., Philipoom, P. R., & Fry, T. D. (1999). Modeling simultaneous worker learning and forgetting in dual resource constrained systems. European Journal of Operational Research, 115(1), 158-172.
Kleiner, B. M., Drury, C. G., & Palepu, P. (1998). A computer-based productivity and quality management system for cellular manufacturing. Computers & industrial engineering, 34(1), 207-217.
Li, Q., Gong, J., Fung, R. Y., & Tang, J. (2012). Multi-objective optimal cross-training configuration models for an assembly cell using non-dominated sorting genetic algorithm-II. International Journal of Computer Integrated Manufacturing, 25(11), 981-995.
Mahdavi, I., Aalaei, A., Paydar, M. M., & Solimanpur, M. (2010). Designing a mathematical model for dynamic cellular manufacturing systems considering production planning and worker assignment. Computers & Mathematics with Applications, 60(4), 1014-1025.
Mahdavi, I., Aalaei, A., Paydar, M. M., & Solimanpur, M. (2012). A new mathematical model for integrating all incidence matrices in multi-dimensional cellular manufacturing system. Journal of Manufacturing Systems, 31(2), 214-223.
McDonald, T., Ellis, K. P., Van Aken, E. M., & Patrick Koelling, C. (2009). Development and application of a worker assignment model to evaluate a lean manufacturing cell. International Journal of Production Research, 47(9), 2427-2447.
Min, H., & Shin, D. (1993). Simultaneous formation of machine and human cells in group technology: a multiple objective approach. THE INTERNATIONAL JOURNAL OF PRODUCTION RESEARCH, 31(10), 2307-2318.
Molleman, E., & Slomp, J. (1999). Functional flexibility and team performance. International Journal of Production Research, 37(8), 1837-1858.
Morris, J. S., & Tersine, R. J. (1994). A simulation comparison of process and cellular layouts in a dual resource constrained environment. Computers & industrial engineering, 26(4), 733-741.
Mosier, C. T., & Mahmoodi, F. (2002). Work sequencing in a manufacturing cell with limited labour constraints. International Journal of Production Research, 40(12), 2883-2899.
Norman, B. A., Tharmmaphornphilas, W., Needy, K. L., Bidanda, B., & Warner, R. C. (2002). Worker assignment in cellular manufacturing considering technical and human skills. International Journal of Production Research, 40(6), 1479-1492.
Olorunniwo, F., & Udo, G. (2002). The impact of management and employees on cellular manufacturing implementation. International Journal of Production Economics, 76(1), 27-38.
Papaioannou, G., & Wilson, J. M. (2010). The evolution of cell formation problem methodologies based on recent studies (1997–2008): Review and directions for future research. European Journal of Operational Research, 206(3), 509-521.
Park, T., & Lee, H. (1995). Design of a manufacturing cell in consideration of multiple objective performance measures. Manufacturing research and technology, 24, 181-202.
Saidi-Mehrabad, M., Paydar, M. M., & Aalaei, A. (2013). Production planning and worker training in dynamic manufacturing systems. Journal of Manufacturing Systems, 32(2), 308-314.
Satoglu, S. I., & Suresh, N. C. (2009). A goal-programming approach for design of hybrid cellular manufacturing systems in dual resource constrained environments. Computers & industrial engineering, 56(2), 560-575.
Slomp, J., Chowdary, B. V., & Suresh, N. C. (2005). Design of virtual manufacturing cells: a mathematical programming approach. Robotics and Computer-Integrated Manufacturing, 21(3), 273-288.
Slomp, J., & Molleman, E. (2000). Cross-training policies and performance of teams. Paper presented at the Group technology/cellular manufacturing world symposium.
Slomp, J., & Suresh, N. C. (2005). The shift team formation problem in multi-shift manufacturing operations. European Journal of Operational Research, 165(3), 708-728.
Süer, G. A., Arikan, F., & Babayiğit, C. (2008). Bi-objective cell loading problem with non-zero setup times with fuzzy aspiration levels in labour intensive manufacturing cells. International Journal of Production Research, 46(2), 371-404.
Suer, G. A., & Cedeño, A. A. (1996). A configuration-based clustering algorithm for family formation. Computers & industrial engineering, 31(1), 147-150.
Tompkins, J., White, J., Bozer, Y., & Tanchoco, J. (2003). Facilities planning. 2003: Wiley, New York.
Xu, J., Xu, X., & Xie, S. (2011). Recent developments in Dual Resource Constrained (DRC) system research. European Journal of Operational Research, 215(2), 309-318.
Yu, Y., Tang, J., Gong, J., Yin, Y., & Kaku, I. (2014). Mathematical analysis and solutions for multi-objective line-cell conversion problem. European Journal of Operational Research, 236(2), 774-786.
Yu, Y., Tang, J., Sun, W., Yin, Y., & Kaku, I. (2013). Reducing worker (s) by converting assembly line into a pure cell system. International Journal of Production Economics, 145(2), 799-806.
Zhang, X., Schmidt, L., Schlick, C., Reuth, R., & Luczak, H. (2008). A human task-oriented simulation study in autonomous production cells. International Journal of Production Research, 46(18), 5013-5041.
Askin, R., & Huang, Y. (1997). Employee training and assignment for facility reconfiguration. Proceedings of the sixth IERC, Miami, FL, 426-431.
Askin, R., & Huang, Y. (2001). Forming effective worker teams for cellular manufacturing. International Journal of Production Research, 39(11), 2431-2451.
Bartholdi, J. J., & Eisenstein, D. D. (1996). A production line that balances itself. Operations Research, 44(1), 21-34.
Black, J., & Schroer, B. J. (1993). Simulation of an apparel assembly cell with walking workers and decouplers. Journal of Manufacturing Systems, 12(2), 170-180.
Cesaní, V. I., & Steudel, H. J. (2005). A study of labor assignment flexibility in cellular manufacturing systems. Computers & industrial engineering, 48(3), 571-591.
Chakravorty, S. S., & Hales, D. N. (2004). Implications of cell design implementation: A case study and analysis. European Journal of Operational Research, 152(3), 602-614.
Chakravorty, S. S., & Hales, D. N. (2008). The evolution of manufacturing cells: An action research study. European Journal of Operational Research, 188(1), 153-168.
Ertay, T., & Ruan, D. (2005). Data envelopment analysis based decision model for optimal operator allocation in CMS. European Journal of Operational Research, 164(3), 800-810.
Fitzpatrick, E. L., & Askin, R. G. (2005). Forming effective worker teams with multi-functional skill requirements. Computers & industrial engineering, 48(3), 593-608.
Gel, E., Hopp, W., & Van Oyen, M. (2000). Workforce agility in systems with hierarchical cross-training. Retrieved from
Hamedi, M., Esmaeilian, G., Ismail, N., & Ariffin, M. (2012). Capability-based virtual cellular manufacturing systems formation in dual-resource constrained settings using Tabu Search. Computers & Industrial Engineering, 62(4), 953-971.
Heady, R. B. (1997). Forming minimum-cost machine cells with exceptional parts using zero-one integer programming. Journal of Manufacturing Systems, 16(2), 79-90.
Hyer, N. L., Brown, K. A., & Zimmerman, S. (1999). A socio-technical systems approach to cell design: case study and analysis. Journal of Operations Management, 17(2), 179-203.
Jensen, J. B. (2000). The impact of resource flexibility and staffing decisions on cellular and departmental shop performance. European Journal of Operational Research, 127(2), 279-296.
Kher, H. V. (2000a). Examination of flexibility acquisition policies in dual resource constrained job shops with simultaneous worker learning and forgetting effects. Journal of the Operational Research Society, 51(5), 592-601.
Kher, H. V. (2000b). Examination of flexibility acquisition policies in dual resource constrained job shops with simultaneous worker learning and forgetting effects. Journal of the Operational Research Society, 592-601.
Kher, H. V., Malhotra, M. K., Philipoom, P. R., & Fry, T. D. (1999). Modeling simultaneous worker learning and forgetting in dual resource constrained systems. European Journal of Operational Research, 115(1), 158-172.
Kleiner, B. M., Drury, C. G., & Palepu, P. (1998). A computer-based productivity and quality management system for cellular manufacturing. Computers & industrial engineering, 34(1), 207-217.
Li, Q., Gong, J., Fung, R. Y., & Tang, J. (2012). Multi-objective optimal cross-training configuration models for an assembly cell using non-dominated sorting genetic algorithm-II. International Journal of Computer Integrated Manufacturing, 25(11), 981-995.
Mahdavi, I., Aalaei, A., Paydar, M. M., & Solimanpur, M. (2010). Designing a mathematical model for dynamic cellular manufacturing systems considering production planning and worker assignment. Computers & Mathematics with Applications, 60(4), 1014-1025.
Mahdavi, I., Aalaei, A., Paydar, M. M., & Solimanpur, M. (2012). A new mathematical model for integrating all incidence matrices in multi-dimensional cellular manufacturing system. Journal of Manufacturing Systems, 31(2), 214-223.
McDonald, T., Ellis, K. P., Van Aken, E. M., & Patrick Koelling, C. (2009). Development and application of a worker assignment model to evaluate a lean manufacturing cell. International Journal of Production Research, 47(9), 2427-2447.
Min, H., & Shin, D. (1993). Simultaneous formation of machine and human cells in group technology: a multiple objective approach. THE INTERNATIONAL JOURNAL OF PRODUCTION RESEARCH, 31(10), 2307-2318.
Molleman, E., & Slomp, J. (1999). Functional flexibility and team performance. International Journal of Production Research, 37(8), 1837-1858.
Morris, J. S., & Tersine, R. J. (1994). A simulation comparison of process and cellular layouts in a dual resource constrained environment. Computers & industrial engineering, 26(4), 733-741.
Mosier, C. T., & Mahmoodi, F. (2002). Work sequencing in a manufacturing cell with limited labour constraints. International Journal of Production Research, 40(12), 2883-2899.
Norman, B. A., Tharmmaphornphilas, W., Needy, K. L., Bidanda, B., & Warner, R. C. (2002). Worker assignment in cellular manufacturing considering technical and human skills. International Journal of Production Research, 40(6), 1479-1492.
Olorunniwo, F., & Udo, G. (2002). The impact of management and employees on cellular manufacturing implementation. International Journal of Production Economics, 76(1), 27-38.
Papaioannou, G., & Wilson, J. M. (2010). The evolution of cell formation problem methodologies based on recent studies (1997–2008): Review and directions for future research. European Journal of Operational Research, 206(3), 509-521.
Park, T., & Lee, H. (1995). Design of a manufacturing cell in consideration of multiple objective performance measures. Manufacturing research and technology, 24, 181-202.
Saidi-Mehrabad, M., Paydar, M. M., & Aalaei, A. (2013). Production planning and worker training in dynamic manufacturing systems. Journal of Manufacturing Systems, 32(2), 308-314.
Satoglu, S. I., & Suresh, N. C. (2009). A goal-programming approach for design of hybrid cellular manufacturing systems in dual resource constrained environments. Computers & industrial engineering, 56(2), 560-575.
Slomp, J., Chowdary, B. V., & Suresh, N. C. (2005). Design of virtual manufacturing cells: a mathematical programming approach. Robotics and Computer-Integrated Manufacturing, 21(3), 273-288.
Slomp, J., & Molleman, E. (2000). Cross-training policies and performance of teams. Paper presented at the Group technology/cellular manufacturing world symposium.
Slomp, J., & Suresh, N. C. (2005). The shift team formation problem in multi-shift manufacturing operations. European Journal of Operational Research, 165(3), 708-728.
Süer, G. A., Arikan, F., & Babayiğit, C. (2008). Bi-objective cell loading problem with non-zero setup times with fuzzy aspiration levels in labour intensive manufacturing cells. International Journal of Production Research, 46(2), 371-404.
Suer, G. A., & Cedeño, A. A. (1996). A configuration-based clustering algorithm for family formation. Computers & industrial engineering, 31(1), 147-150.
Tompkins, J., White, J., Bozer, Y., & Tanchoco, J. (2003). Facilities planning. 2003: Wiley, New York.
Xu, J., Xu, X., & Xie, S. (2011). Recent developments in Dual Resource Constrained (DRC) system research. European Journal of Operational Research, 215(2), 309-318.
Yu, Y., Tang, J., Gong, J., Yin, Y., & Kaku, I. (2014). Mathematical analysis and solutions for multi-objective line-cell conversion problem. European Journal of Operational Research, 236(2), 774-786.
Yu, Y., Tang, J., Sun, W., Yin, Y., & Kaku, I. (2013). Reducing worker (s) by converting assembly line into a pure cell system. International Journal of Production Economics, 145(2), 799-806.
Zhang, X., Schmidt, L., Schlick, C., Reuth, R., & Luczak, H. (2008). A human task-oriented simulation study in autonomous production cells. International Journal of Production Research, 46(18), 5013-5041.