In today-s global and competitive market,
manufacturing companies are working hard towards improving their
production system performance. Most companies develop production
systems that can help in cost reduction. Manufacturing systems
consist of different elements including production methods,
machines, processes, control and information systems. Human issues
are an important part of manufacturing systems, yet most companies
do not pay sufficient attention to them. In this paper, a workforce
planning (WP) model is presented. A non-linear programming model
is developed in order to minimize the hiring, firing, training and
overtime costs. The purpose is to determine the number of workers
for each worker type, the number of workers trained, and the number
of overtime hours. Moreover, a decision support system (DSS) based
on the proposed model is introduced using the Excel-Lingo software
interfacing feature. This model will help to improve the interaction
between the workers, managers and the technical systems in
manufacturing.
[1] M. D. Byrne, and M. A. Bakir, M.A., "Production planning using a
hybrid simulation-analytical approach," International Journal of
Production Economics, vol. 59, no. 305-311, 1999.
[2] M. B. Aryanezhad, V. Deljoo, and S. M. J. Al-e-hashem, "Dynamic cell
formation and the worker assignment problem: a new model," The
International Journal of Advanced Manufacturing Technology, vol. 41,
no. 3-4, pp. 329-342, 2009.
[3] B. Bidanda, P. Ariyawonggrat, K. M. Needy, B. A. Norman, and W.
Tharmmaphornphilas, "Human related issues in manufacturing cell
design, implementation, and operation: a review and survey," Computers
& Industrial Engineering, vol. 48, no. 507-523, 2005.
[4] P. Oborski, "Man-machine interactions in advanced manufacturing
systems," International Journal of Advanced Manufacturing
Technology, vol. 23, no. 3-4, pp. 227-232, 2004.
[5] G. Udo and A. Ebiefung, "Human factors affecting the success of
advanced manufacturing systems," Computers & Industrial Engineering,
vol. 37, pp. 297-300, 1999.
[6] C. W. Clegg, et al., "An international survey of the use and effectiveness
of modern manufacturing practices," Human Factors and Ergonomics in
Manufacturing, vol. 12, no. 2, pp.171-191, 2002.
[7] J. A. Buzacott, "The impact of worker differences on production system
output," International Journal of Ergonomics Economics, vol. 78, no.
37-44, 2002.
[8] M. Berglund, and J. Karltun, "Human, technological and organizational
aspects influencing the production scheduling process," International
Journal of Production Economics, vol. 110, no. 1-2, pp. 160-174, 2007.
[9] P. L. Jensen, "Human factors and ergonomics in the planning of
production," International Journal of Industrial Ergonomics, vol. 29,
pp. 121-131, 2002.
[10] P. Wirojanagud, E. S. Gel, J. W. Fowler, and R. Cardy, "Modeling
inherent worker differences for workforce planning," International
Journal of Production Research, vol. 45, no. 3, pp. 525-553, 2007.
[11] H-C. Huang, L-H. Lee, H. Song, and B. T. Eck, "SimMan-A simulation
model for workforce capacity planning," Computers & Operations
Research, vol. 36, no. 8, pp. 2490-2497, 2008.
[12] B. A. Norman, W. Tharmmaphornphilas, K. L. Needy, B. Bidanda, and
R. C. Warner, "Worker assignment in cellular manufacturing
considering technical and human skills," International Journal of
Production Research vol. 40, no. 6, pp. 1479-1492, 2002.
[13] Y. Y. Lee, "Fuzzy set theory approach to aggregate production planning
and inventory control," Ph.D. Dissertation. Department of I.E., Kansas
State University, 1990.
[14] J. B. Mazzola, A. W. Neebe, and C. M. Rump, "Multiproduct production
planning in the presence of work-force learning," European Journal of
Operational Research, vol. 106, no. 2-3, pp. 336-356, 1998.
[15] R. C. Wang, and H. H. Fang, "Aggregate production planning with
multiple objectives in a fuzzy environment," European Journal of
Operational Research, vol. 133, pp. 521-536, 2001.
[16] J. Tang, R. Y. K. Fung, and K-L. Yung, "Fuzzy modeling and simulation
for aggregate production planning," International Journal of Systems
Science, vol. 34, no. 12-13, pp. 661-673, 2003.
[17] R. C. Wang, and T. F. Liang, "Application of fuzzy multi-objective
linear programming to aggregate production planning," Computers &
Industrial Engineering, vol. 46, pp. 17-41, 2004.
[18] L. Pradenas, and F. Pe├▒ailillo, and J. Ferland, "Aggregate production
planning problem. A new algorithm," Electronic Notes in Discrete
Mathematics, vol. 18, pp. 193-199, 2004.
[19] A. Jain, and U. S. Palekar, "Aggregate production planning for a
continuous reconfigurable manufacturing process," Computers &
Operations Research, vol. 32, no. 1213-1236, 2005.
[20] R. C. Wang, and T. F. Liang, "Applying possibilistic linear
programming to aggregate production planning," International Journal
of Production Economics, vol. 98, pp. 328-341, 2005.
[21] C. G. Da Silva, J. Figueira, J. Lisboa, and S. Barman, "An interactive
decision support system for an aggregate production planning model
based on multiple criteria mixed integer linear programming," The
International Journal of Management Science, vol. 34, no. 167-177,
2006.
[22] S. Leung, and S. Chan, "A goal programming model for aggregate
production planning with resource utilization constraint," Computers
and Industrial Engineering, vol. 56, pp. 1053-1064, 2009.
[23] A. Jamalnia, and M. A. Soukhakian, "A hybrid fuzzy goal programming
approach with different goal priorities to aggregate production
planning," Computers & Industrial Engineering, vol. 56, no. 4, pp.
1474-1486, 2009.
[24] J. Tang, R. Y. K. Fung, and K-L. Yung, "Fuzzy modeling and simulation
for aggregate production planning," International Journal of Systems
Science, vol. 34, no. 12-13, pp. 661-673, 2003.
[25] S. C. K. Chu, "A mathematical programming approach towards
optimized master production scheduling," International Journal of
Production Economics, vol. 38, no. 2-3,pp. 269-279, 1995.
[26] S. J. Nam, and R. Logendran, "Aggregate production planning - A
survey of models and methodologies," European Journal of Operational
Research, vol. 61, no. 255-272, 1992.
[1] M. D. Byrne, and M. A. Bakir, M.A., "Production planning using a
hybrid simulation-analytical approach," International Journal of
Production Economics, vol. 59, no. 305-311, 1999.
[2] M. B. Aryanezhad, V. Deljoo, and S. M. J. Al-e-hashem, "Dynamic cell
formation and the worker assignment problem: a new model," The
International Journal of Advanced Manufacturing Technology, vol. 41,
no. 3-4, pp. 329-342, 2009.
[3] B. Bidanda, P. Ariyawonggrat, K. M. Needy, B. A. Norman, and W.
Tharmmaphornphilas, "Human related issues in manufacturing cell
design, implementation, and operation: a review and survey," Computers
& Industrial Engineering, vol. 48, no. 507-523, 2005.
[4] P. Oborski, "Man-machine interactions in advanced manufacturing
systems," International Journal of Advanced Manufacturing
Technology, vol. 23, no. 3-4, pp. 227-232, 2004.
[5] G. Udo and A. Ebiefung, "Human factors affecting the success of
advanced manufacturing systems," Computers & Industrial Engineering,
vol. 37, pp. 297-300, 1999.
[6] C. W. Clegg, et al., "An international survey of the use and effectiveness
of modern manufacturing practices," Human Factors and Ergonomics in
Manufacturing, vol. 12, no. 2, pp.171-191, 2002.
[7] J. A. Buzacott, "The impact of worker differences on production system
output," International Journal of Ergonomics Economics, vol. 78, no.
37-44, 2002.
[8] M. Berglund, and J. Karltun, "Human, technological and organizational
aspects influencing the production scheduling process," International
Journal of Production Economics, vol. 110, no. 1-2, pp. 160-174, 2007.
[9] P. L. Jensen, "Human factors and ergonomics in the planning of
production," International Journal of Industrial Ergonomics, vol. 29,
pp. 121-131, 2002.
[10] P. Wirojanagud, E. S. Gel, J. W. Fowler, and R. Cardy, "Modeling
inherent worker differences for workforce planning," International
Journal of Production Research, vol. 45, no. 3, pp. 525-553, 2007.
[11] H-C. Huang, L-H. Lee, H. Song, and B. T. Eck, "SimMan-A simulation
model for workforce capacity planning," Computers & Operations
Research, vol. 36, no. 8, pp. 2490-2497, 2008.
[12] B. A. Norman, W. Tharmmaphornphilas, K. L. Needy, B. Bidanda, and
R. C. Warner, "Worker assignment in cellular manufacturing
considering technical and human skills," International Journal of
Production Research vol. 40, no. 6, pp. 1479-1492, 2002.
[13] Y. Y. Lee, "Fuzzy set theory approach to aggregate production planning
and inventory control," Ph.D. Dissertation. Department of I.E., Kansas
State University, 1990.
[14] J. B. Mazzola, A. W. Neebe, and C. M. Rump, "Multiproduct production
planning in the presence of work-force learning," European Journal of
Operational Research, vol. 106, no. 2-3, pp. 336-356, 1998.
[15] R. C. Wang, and H. H. Fang, "Aggregate production planning with
multiple objectives in a fuzzy environment," European Journal of
Operational Research, vol. 133, pp. 521-536, 2001.
[16] J. Tang, R. Y. K. Fung, and K-L. Yung, "Fuzzy modeling and simulation
for aggregate production planning," International Journal of Systems
Science, vol. 34, no. 12-13, pp. 661-673, 2003.
[17] R. C. Wang, and T. F. Liang, "Application of fuzzy multi-objective
linear programming to aggregate production planning," Computers &
Industrial Engineering, vol. 46, pp. 17-41, 2004.
[18] L. Pradenas, and F. Pe├▒ailillo, and J. Ferland, "Aggregate production
planning problem. A new algorithm," Electronic Notes in Discrete
Mathematics, vol. 18, pp. 193-199, 2004.
[19] A. Jain, and U. S. Palekar, "Aggregate production planning for a
continuous reconfigurable manufacturing process," Computers &
Operations Research, vol. 32, no. 1213-1236, 2005.
[20] R. C. Wang, and T. F. Liang, "Applying possibilistic linear
programming to aggregate production planning," International Journal
of Production Economics, vol. 98, pp. 328-341, 2005.
[21] C. G. Da Silva, J. Figueira, J. Lisboa, and S. Barman, "An interactive
decision support system for an aggregate production planning model
based on multiple criteria mixed integer linear programming," The
International Journal of Management Science, vol. 34, no. 167-177,
2006.
[22] S. Leung, and S. Chan, "A goal programming model for aggregate
production planning with resource utilization constraint," Computers
and Industrial Engineering, vol. 56, pp. 1053-1064, 2009.
[23] A. Jamalnia, and M. A. Soukhakian, "A hybrid fuzzy goal programming
approach with different goal priorities to aggregate production
planning," Computers & Industrial Engineering, vol. 56, no. 4, pp.
1474-1486, 2009.
[24] J. Tang, R. Y. K. Fung, and K-L. Yung, "Fuzzy modeling and simulation
for aggregate production planning," International Journal of Systems
Science, vol. 34, no. 12-13, pp. 661-673, 2003.
[25] S. C. K. Chu, "A mathematical programming approach towards
optimized master production scheduling," International Journal of
Production Economics, vol. 38, no. 2-3,pp. 269-279, 1995.
[26] S. J. Nam, and R. Logendran, "Aggregate production planning - A
survey of models and methodologies," European Journal of Operational
Research, vol. 61, no. 255-272, 1992.
@article{"International Journal of Mechanical, Industrial and Aerospace Sciences:49323", author = "M. Othman and N. Bhuiyan and G. J. Gouw", title = "A New Approach to Workforce Planning", abstract = "In today-s global and competitive market,
manufacturing companies are working hard towards improving their
production system performance. Most companies develop production
systems that can help in cost reduction. Manufacturing systems
consist of different elements including production methods,
machines, processes, control and information systems. Human issues
are an important part of manufacturing systems, yet most companies
do not pay sufficient attention to them. In this paper, a workforce
planning (WP) model is presented. A non-linear programming model
is developed in order to minimize the hiring, firing, training and
overtime costs. The purpose is to determine the number of workers
for each worker type, the number of workers trained, and the number
of overtime hours. Moreover, a decision support system (DSS) based
on the proposed model is introduced using the Excel-Lingo software
interfacing feature. This model will help to improve the interaction
between the workers, managers and the technical systems in
manufacturing.", keywords = "Decision Support System, Human Factors,Manufacturing System, Workforce Planning.", volume = "5", number = "4", pages = "738-7", }
