Abstract
By the nature of this problem domain, this volume has ranged widely over a great deal of ground, and we hope that the reader has found the journey worthwhile. This chapter concludes the book with a brief review of the principal results and their implications for future work, both related to the clearing functions that are the central concern of this volume and for the broader field of production planning models.
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References
Albey E, Uzsoy R (2016) A chance constraint based multi-item production planning model using simulation optimization. In: Winter simulation conference, Arlington, VA
Albey E, Bilge U, Uzsoy R (2014) An exploratory study of disaggregated clearing functions for multiple product single machine production environments. Int J Prod Res 52(18):5301–5322
Albey E, Norouzi A, Kempf KG, Uzsoy R (2015) Demand modeling with forecast evolution: an application to production planning. IEEE Trans Semicond Manuf 28(3):374–384
Albey E, Bilge U, Uzsoy R (2017) Multi-dimensional clearing functions for aggregate capacity modelling in multi-stage production systems. Int J Prod Res 55(14):4164–4179
Aouam T, Uzsoy R (2012) Chance-constraint-based heuristics for production planning in the face of stochastic demand and workload-dependent lead times. In: Armbruster D, Kempf KG (eds) Decision policies for production networks. Springer, London, pp 173–208
Aouam T, Uzsoy R (2015) Zero-order production planning models with stochastic demand and workload-dependent lead times. Int J Prod Res 53(6):1–19
Arrow KJ, Karlin S, Scarf H (1958) Studies in the mathematical theory of inventory and production. Stanford University Press, Stanford
Askin RG, Hanumantha GJ (2018) Queueing network models for analysis of nonstationary manufacturing systems. Int J Prod Res 56(1–2):22–42
Asmundsson J, Rardin RL, Uzsoy R (2006) Tractable nonlinear production planning models for semiconductor wafer fabrication facilities. IEEE Trans Semicond Manuf 19(1):95–111
Asmundsson JM, Rardin RL, Turkseven CH, Uzsoy R (2009) Production planning models with resources subject to congestion. Nav Res Logist 56(2):142–157
Aytug H, Lawley MA, McKay KN, Mohan S, Uzsoy R (2005) Executing production schedules in the face of uncertainty: a review and some future directions. Eur J Oper Res 161:86–110
Baker KR (1993) Requirements planning. In: Graves SC, AHG RK, Zipkin PH (eds) Handbooks in operations research and management science. Logistics of production and inventory, vol 3. Elsevier Science Publishers, Amsterdam, pp 571–627
Barton RR, Meckesheimer M (2006) Chapter 18: Metamodel-based simulation optimization. In: Henderson SG, Nelson BL (eds) Handbooks in operations research and management science, vol 13. Elsevier, Amsterdam, pp 535–574
Bertsimas D, Dunn J, Mundru N (2019) Optimal prescriptive trees. INFORMS Journal on Optimization 1(2):164–183
Buffa ES, Taubert WH (1972) Production-inventory systems; planning and control. R. D. Irwin, Homewood
Carey M (1987) Optimal time-varying flows on congested networks. Oper Res 35(1):58–69
Carey M (1990) Extending and solving a multiperiod congested network flow model. Comput Oper Res 17(5):495–507
Carey M, Bowers M (2012) A review of properties of flow–density functions. Transp Rev 32(1):49–73
Carey M, Subrahmanian E (2000) An approach to modelling time-varying flows on congested networks. Trans Res B Methodol 34:157–183
de Kok AG, Fransoo JC (2003) Planning supply chain operations: definition and comparison of planning concepts. In: de Kok AG, Graves SC (eds) Handbooks in operations research and management science. Supply chain management: design, coordination and operation, vol 11. Elsevier, Amsterdam, pp 597–675
Fine CH, Graves SC (1989) A tactical planning model for manufacturing subcomponents of mainframe computers. J Manuf Oper Manag 2:4–34
Fu MC (ed) (2015) Handbook of simulation optimization. Springer, New York
Gopalswamy K, Uzsoy R (2019) A data-driven iterative refinement approach for estimating clearing functions from simulation models of production systems. Int J Prod Res 57(19):6013–6030
Gopalswamy K, Fathi Y, Uzsoy R (2019) Valid inequalities for concave piecewise linear regression. Oper Res Lett 47:52–58
Gorissen BL, Yanikoglu I, den Hertog D (2015) A practical guide to robust optimization. Omega 53:124–137
Graves SC (1986) A tactical planning model for a job shop. Oper Res 34(4):522–533
Graves SC (1988) Safety stocks in manufacturing systems. J Manuf Oper Manag 1:67–101
Greenberg HJ (1996) The analyze rulebase for supporting LP analysis. Ann Oper Res 65:91–126
Hackman ST (2008) Production economics: integrating the microeconomic and engineering perspectives. Springer, Berlin
Hanssmann F (1959) Optimal inventory location and control in production and distribution networks. Oper Res 7(4):483–498
Häussler S, Missbauer H (2014) Empirical validation of meta-models of work centres in order release planning. Int J Prod Econ 149:102–116
Häussler S, Schneckenreither M (2019) Adaptive order release planning with dynamic lead times: a machine learning approach. University of Innsbruck, Innsbruck
Holt CC, Modigliani F, Muth JF, Simon HA (1960) Planning production, inventories and work force. Prentice Hall, Englewood Cliffs
Hopp WJ, Spearman ML (2008) Factory physics: foundations of manufacturing management. Irwin/McGraw-Hill, Boston
Hung YF, Leachman RC (1996) A production planning methodology for semiconductor manufacturing based on iterative simulation and linear programming calculations. IEEE Trans Semicond Manuf 9(2):257–269
Jacobs FR, Berry WL, Whybark DC, Vollmann TE (2011) Manufacturing planning and control for supply chain management. Irwin/McGraw-Hill, New York
Jansen MM, de Kok TG, Fransoo JC (2013) Lead time anticipation in supply chain operations planning. OR Spectr 35(1):251–290
Johnson LA, Montgomery DC (1974) Operations research in production planning, scheduling and inventory control. Wiley, New York
Kacar NB, Uzsoy R (2015) Estimating clearing functions for production resources using simulation optimization. IEEE Trans Autom Sci Eng 12(2):539–552
Karmarkar US (1987) Lot sizes, lead times and in-process inventories. Manag Sci 33(3):409–418
Karmarkar US (1989) Capacity loading and release planning with work-in-progress (WIP) and lead-times. J Manuf Oper Manag 2(1):105–123
Karmarkar US, Kekre S, Kekre S (1992) Multi-item batching heuristics for minimization of queues. Eur J Oper Res 58:99–111
Kock AAA, Veeger CPL, Etman LFP, Lemmen B, Rooda JE (2011) Lumped parameter modelling of the litho cell. Prod Plan Control 22(1):41–49
Law AM, Kelton WD (2004) Simulation modeling and analysis. McGraw-Hill, New York
Lee CY, Piramuthu S, Tsai YK (1997) Job shop scheduling with a genetic algorithm and machine learning. Int J Prod Res 35(4):1171–1191
Li M, Yang F, Uzsoy R, Xu J (2016) A metamodel-based Monte Carlo simulation approach for responsive production planning of manufacturing systems. J Manuf Syst 38:114–133
Orcun S, Uzsoy R, Kempf KG (2009) An integrated production planning model with load-dependent lead-times and safety stocks. Comput Chem Eng 33(12):2159–2163
Orlicky J (1975) Material requirements planning: the new way of life in production and inventory management. McGraw-Hill, New York
Paternina-Arboleda CD, Das TK (2001) Intelligent dynamic control policies for serial production lines. IIE Trans 33(1):65–77
Srinivasan A, Carey M, Morton TE (1988) Resource pricing and aggregate scheduling in manufacturing systems. Graduate School of Industrial Administration, Carnegie-Mellon University, Pittsburgh
Stadtler H, Kilger C, Meyr H (2015) Supply chain management and advanced planning. Concepts, models, software, and case studies. Springer, Berlin
Sterman JD (2000) Business dynamics: systems thinking and modeling for a complex world. McGraw-Hill, New York
Toriello A, Vielma JP (2012) Fitting piecewise linear continuous functions. Eur J Oper Res 219:86–95
Veeger CPL, Etman LFP, Lefeber E, Adan IJBF, van Herk J, Rooda JE (2011) Predicting cycle time distributions for integrated processing workstations: an aggregate modeling approach. IEEE Trans Semicond Manuf 24(2):223–236
Voss S, Woodruff DL (2006) Introduction to computational optimization models for production planning in a supply chain. Springer, New York
Yang F, Liu J (2012) Simulation-based transfer function modeling for transient analysis of general queueing systems. Eur J Oper Res 223(1):150–166
Zäpfel G, Missbauer H (1993) Production planning and control (PPC) systems including load-oriented order release—problems and research perspectives. Int J Prod Econ 30/31:107–122
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Missbauer, H., Uzsoy, R. (2020). Conclusions and Future Directions. In: Production Planning with Capacitated Resources and Congestion. Springer, New York, NY. https://doi.org/10.1007/978-1-0716-0354-3_11
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