How to cite this paper
Rabbani, M., Monshi, M., Manavizadeh, N & Jalali, M. (2016). Designing an advanced available-to-promise mechanism compatible with the make-to-forecast production systems through integrating inventory allocation and job shop scheduling with due dates and weighte.International Journal of Industrial Engineering Computations , 7(3), 451-462.
Refrences
Akinc, U., & Meredith, J. (2006). Choosing the appropriate capacity for a make-to-forecast production environment using a Markov analysis approach. IIE Transactions, 38(10), 847-858.
Meredith, J., & Akinc, U. (2007). Characterizing and structuring a new make-to-forecast production strategy. Journal of Operations Management, 25(3), 623-642.
Alemany, M. M. E., Lario, F. C., Ortiz, A., & G?mez, F. (2013). Available-To-Promise modeling for multi-plant manufacturing characterized by lack of homogeneity in the product: An illustration of a ceramic case. Applied Mathematical Modelling, 37(5), 3380-3398.
Almeder, C., & Hartl, R. F. (2013). A metaheuristic optimization approach for a real-world stochastic flexible flow shop problem with limited buffer. International Journal of Production Economics, 145(1), 88-95.
Dictionary, A. P. I. C. S. (2004). Published by the American Production and Inventory Control Society. Alexandria, VA.
Beamon, B. M. (1998). Supply chain design and analysis: Models and methods. International journal of production economics, 55(3), 281-294.
Behnamian, J., & Ghomi, S. F. (2013). The heterogeneous multi-factory production network scheduling with adaptive communication policy and parallel machine. Information Sciences, 219, 181-196.
Chen, C. Y., Zhao, Z. Y., & Ball, M. O. (2001). Quantity and due date quoting available to promise. Information Systems Frontiers, 3(4), 477-488.
Chien-Yu, C., Zhao, Z., & Ball, M. O. (2002). A model for batch advanced available-to-promise. Production and Operations Management, 11(4), 424.
Cheng, C. B., & Cheng, C. J. (2011). Available-to-promise based bidding decision by fuzzy mathematical programming and genetic algorithm.Computers & Industrial Engineering, 61(4), 993-1002.
Chen-Ritzo, C. H., Ervolina, T., Harrison, T. P., & Gupta, B. (2011). Component rationing for available-to-promise scheduling in configure-to-order systems.European Journal of Operational Research, 211(1), 57-65.
Eskandari, H., & Hosseinzadeh, A. (2013). A variable neighbourhood search for hybrid flow-shop scheduling problem with rework and set-up times. Journal of the Operational Research Society, 65(8), 1221-1231.
Figueira, G., Santos, M. O., & Almada-Lobo, B. (2013). A hybrid VNS approach for the short-term production planning and scheduling: A case study in the pulp and paper industry. Computers & Operations Research, 40(7), 1804-1818.
Fischer, M. E. (2001). Available-to-promise: Aufgaben und Verfahren im Rahmen des Supply-Chain-Management. Roderer.
Han, S. H., Dong, M. Y., Lu, S. X., Leung, S. C., & Lim, M. K. (2012). Production planning for hybrid remanufacturing and manufacturing system with component recovery. Journal of the Operational Research Society, 64(10), 1447-1460.
Jeong, B., Sim, S. B., Jeong, H. S., & Kim, S. W. (2002). An available-to-promise system for TFT LCD manufacturing in supply chain. Computers & Industrial Engineering, 43(1), 191-212.
Zanjani, M. K., Nourelfath, M., & Ait-Kadi, D. (2013). A scenario decomposition approach for stochastic production planning in sawmills. Journal of the Operational Research Society, 64(1), 48-59.
Lamghari, A., & Dimitrakopoulos, R. (2012). A diversified Tabu search approach for the open-pit mine production scheduling problem with metal uncertainty. European Journal of Operational Research, 222(3), 642-652.
Lamghari, A., Dimitrakopoulos, R., & Ferland, J. A. (2013). A variable neighbourhood descent algorithm for the open-pit mine production scheduling problem with metal uncertainty. Journal of the Operational Research Society,65(9), 1305-1314.
Li, X., Baki, F., Tian, P., & Chaouch, B. A. (2014). A robust block-chain based tabu search algorithm for the dynamic lot sizing problem with product returns and remanufacturing. Omega, 42(1), 75-87.
Lin, J. T., Hong, I. H., Wu, C. H., & Wang, K. S. (2010). A model for batch available-to-promise in order fulfillment processes for TFT-LCD production chains. Computers & Industrial Engineering, 59(4), 720-729.
Merdan, M., Moser, T., Sunindyo, W., Biffl, S., & Vrba, P. (2013). Workflow scheduling using multi-agent systems in a dynamically changing environment.Journal of Simulation, 7(3), 144-158.
Toledo, C. F. M., da Silva Arantes, M., De Oliveira, R. R. R., & Almada-Lobo, B. (2013). Glass container production scheduling through hybrid multi-population based evolutionary algorithm. Applied Soft Computing, 13(3), 1352-1364.
Pibernik, R. (2005). Advanced available-to-promise: Classification, selected methods and requirements for operations and inventory management.International journal of production economics, 93, 239-252.
Rudek, A., & Rudek, R. (2013). Makespan minimization flowshop with position dependent job processing times—computational complexity and solution algorithms. Computers & Operations Research, 40(8), 2071-2082.
Schwendinger, J. (1979). Master production scheduling’s available-to-promise. In APICS conference proceedings (Vol. 316, p. 330).
Seker, A., Erol, S., & Botsali, R. (2013). A neuro-fuzzy model for a new hybrid integrated Process Planning and Scheduling system. Expert Systems with Applications, 40(13), 5341-5351.
Volling, T., & Spengler, T. S. (2011). Modeling and simulation of order-driven planning policies in build-to-order automobile production. International Journal of Production Economics, 131(1), 183-193.
Wang, H. F., & Zheng, K. W. (2013). Application of fuzzy linear programming to aggregate production plan of a refinery industry in Taiwan. Journal of the Operational Research Society, 64(2), 169-184.
Wauters, T., Verbeeck, K., Verstraete, P., Berghe, G. V., & De Causmaecker, P. (2012). Real-world production scheduling for the food industry: An integrated approach. Engineering Applications of Artificial Intelligence, 25(2), 222-228.
KEVIN WENG, Z. (1999). Strategies for integrating lead time and customer-order decisions. IIE transactions, 31(2), 161-171.
Xiong, M., Tor, S. B., Khoo, L. P., & Chen, C. H. (2003). A web-enhanced dynamic BOM-based available-to-promise system. International Journal of Production Economics, 84(2), 133-147.
Zhao, Z., Ball, M. O., & Kotake, M. (2005). Optimization-based available-to-promise with multi-stage resource availability. Annals of Operations Research,135(1), 65-85.
Meredith, J., & Akinc, U. (2007). Characterizing and structuring a new make-to-forecast production strategy. Journal of Operations Management, 25(3), 623-642.
Alemany, M. M. E., Lario, F. C., Ortiz, A., & G?mez, F. (2013). Available-To-Promise modeling for multi-plant manufacturing characterized by lack of homogeneity in the product: An illustration of a ceramic case. Applied Mathematical Modelling, 37(5), 3380-3398.
Almeder, C., & Hartl, R. F. (2013). A metaheuristic optimization approach for a real-world stochastic flexible flow shop problem with limited buffer. International Journal of Production Economics, 145(1), 88-95.
Dictionary, A. P. I. C. S. (2004). Published by the American Production and Inventory Control Society. Alexandria, VA.
Beamon, B. M. (1998). Supply chain design and analysis: Models and methods. International journal of production economics, 55(3), 281-294.
Behnamian, J., & Ghomi, S. F. (2013). The heterogeneous multi-factory production network scheduling with adaptive communication policy and parallel machine. Information Sciences, 219, 181-196.
Chen, C. Y., Zhao, Z. Y., & Ball, M. O. (2001). Quantity and due date quoting available to promise. Information Systems Frontiers, 3(4), 477-488.
Chien-Yu, C., Zhao, Z., & Ball, M. O. (2002). A model for batch advanced available-to-promise. Production and Operations Management, 11(4), 424.
Cheng, C. B., & Cheng, C. J. (2011). Available-to-promise based bidding decision by fuzzy mathematical programming and genetic algorithm.Computers & Industrial Engineering, 61(4), 993-1002.
Chen-Ritzo, C. H., Ervolina, T., Harrison, T. P., & Gupta, B. (2011). Component rationing for available-to-promise scheduling in configure-to-order systems.European Journal of Operational Research, 211(1), 57-65.
Eskandari, H., & Hosseinzadeh, A. (2013). A variable neighbourhood search for hybrid flow-shop scheduling problem with rework and set-up times. Journal of the Operational Research Society, 65(8), 1221-1231.
Figueira, G., Santos, M. O., & Almada-Lobo, B. (2013). A hybrid VNS approach for the short-term production planning and scheduling: A case study in the pulp and paper industry. Computers & Operations Research, 40(7), 1804-1818.
Fischer, M. E. (2001). Available-to-promise: Aufgaben und Verfahren im Rahmen des Supply-Chain-Management. Roderer.
Han, S. H., Dong, M. Y., Lu, S. X., Leung, S. C., & Lim, M. K. (2012). Production planning for hybrid remanufacturing and manufacturing system with component recovery. Journal of the Operational Research Society, 64(10), 1447-1460.
Jeong, B., Sim, S. B., Jeong, H. S., & Kim, S. W. (2002). An available-to-promise system for TFT LCD manufacturing in supply chain. Computers & Industrial Engineering, 43(1), 191-212.
Zanjani, M. K., Nourelfath, M., & Ait-Kadi, D. (2013). A scenario decomposition approach for stochastic production planning in sawmills. Journal of the Operational Research Society, 64(1), 48-59.
Lamghari, A., & Dimitrakopoulos, R. (2012). A diversified Tabu search approach for the open-pit mine production scheduling problem with metal uncertainty. European Journal of Operational Research, 222(3), 642-652.
Lamghari, A., Dimitrakopoulos, R., & Ferland, J. A. (2013). A variable neighbourhood descent algorithm for the open-pit mine production scheduling problem with metal uncertainty. Journal of the Operational Research Society,65(9), 1305-1314.
Li, X., Baki, F., Tian, P., & Chaouch, B. A. (2014). A robust block-chain based tabu search algorithm for the dynamic lot sizing problem with product returns and remanufacturing. Omega, 42(1), 75-87.
Lin, J. T., Hong, I. H., Wu, C. H., & Wang, K. S. (2010). A model for batch available-to-promise in order fulfillment processes for TFT-LCD production chains. Computers & Industrial Engineering, 59(4), 720-729.
Merdan, M., Moser, T., Sunindyo, W., Biffl, S., & Vrba, P. (2013). Workflow scheduling using multi-agent systems in a dynamically changing environment.Journal of Simulation, 7(3), 144-158.
Toledo, C. F. M., da Silva Arantes, M., De Oliveira, R. R. R., & Almada-Lobo, B. (2013). Glass container production scheduling through hybrid multi-population based evolutionary algorithm. Applied Soft Computing, 13(3), 1352-1364.
Pibernik, R. (2005). Advanced available-to-promise: Classification, selected methods and requirements for operations and inventory management.International journal of production economics, 93, 239-252.
Rudek, A., & Rudek, R. (2013). Makespan minimization flowshop with position dependent job processing times—computational complexity and solution algorithms. Computers & Operations Research, 40(8), 2071-2082.
Schwendinger, J. (1979). Master production scheduling’s available-to-promise. In APICS conference proceedings (Vol. 316, p. 330).
Seker, A., Erol, S., & Botsali, R. (2013). A neuro-fuzzy model for a new hybrid integrated Process Planning and Scheduling system. Expert Systems with Applications, 40(13), 5341-5351.
Volling, T., & Spengler, T. S. (2011). Modeling and simulation of order-driven planning policies in build-to-order automobile production. International Journal of Production Economics, 131(1), 183-193.
Wang, H. F., & Zheng, K. W. (2013). Application of fuzzy linear programming to aggregate production plan of a refinery industry in Taiwan. Journal of the Operational Research Society, 64(2), 169-184.
Wauters, T., Verbeeck, K., Verstraete, P., Berghe, G. V., & De Causmaecker, P. (2012). Real-world production scheduling for the food industry: An integrated approach. Engineering Applications of Artificial Intelligence, 25(2), 222-228.
KEVIN WENG, Z. (1999). Strategies for integrating lead time and customer-order decisions. IIE transactions, 31(2), 161-171.
Xiong, M., Tor, S. B., Khoo, L. P., & Chen, C. H. (2003). A web-enhanced dynamic BOM-based available-to-promise system. International Journal of Production Economics, 84(2), 133-147.
Zhao, Z., Ball, M. O., & Kotake, M. (2005). Optimization-based available-to-promise with multi-stage resource availability. Annals of Operations Research,135(1), 65-85.