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• W4205557572 abstract "Free Access References Tadeusz Sawik, Tadeusz Sawik AGH University of Science and Technology, Kraków, PolandSearch for more papers by this author Book Author(s):Tadeusz Sawik, Tadeusz Sawik AGH University of Science and Technology, Kraków, PolandSearch for more papers by this author First published: 13 May 2011 https://doi.org/10.1002/9781118029114.refs AboutPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL Share a linkShare onFacebookTwitterLinked InRedditWechat References Abadi, I.N.K., N.G. Hall and C. Sriskandarajah (2000). Minimizing cycle time in a blocking flowshop, Operations Research 48, 177– 180. CrossrefWeb of Science®Google Scholar Agnetis, A., D. Pacciarelli and F. Rossi (1997). Batch scheduling in a two-machine flow shop with limited buffer, Discrete Applied Mathematics 72(3), 243– 260. CrossrefWeb of Science®Google Scholar Agnetis, A., F. Rossi and G. Gristina (1998). An exact algorithm for the batch sequencing problem in a two-machine flow shop with limited buffer, Naval Research Logistics 45(2), 141– 164. Wiley Online LibraryWeb of Science®Google Scholar Agnetis, A., N.G. Hall and D. Pacciarelli (2006). Supply chain scheduling: Sequence coordination, Discrete Applied Mathematics 154, 2044– 2063. CrossrefWeb of Science®Google Scholar Ahmadi, J., R. Ahmadi, H. Matsuo and D. Tirupati (1995). Component fixture positioning/sequencing for printed circuit board assembly with concurrent operations, Operations Research 43, 444– 457. CrossrefWeb of Science®Google Scholar Aissaoui, N., M. Haouari and E. Hassini (2007). Supplier selection and order lot sizing modeling: A review, Computers & Operations Research 34, 3516– 3540. CrossrefWeb of Science®Google Scholar Akkan, C. (1997). Finite-capacity schedulingbased planning for revenue-based capacity managament, European Journal of Operational Research 100, 170– 179. CrossrefWeb of Science®Google Scholar Alfieri, A. (2009). Workload simulation and optimisation in multi-criteria hybrid flowshop scheduling: A case study, International Journal of Production Research 47(18), 5129– 5145. CrossrefWeb of Science®Google Scholar Alves, M.J. and J. Climaco (2007). A review of interactive methods for multiobjective integer and mixed-integer programming, European Journal of Operational Research 180, 99– 115. CrossrefWeb of Science®Google Scholar Amaro, A.C.S. and A.P.F.D. Barbosa-Póvoa (2008). Supply chain management with optimal scheduling, Industrial Engineering and Chemical Research 47(1), 116– 132. CrossrefCASWeb of Science®Google Scholar Anthony, R.N. (1965). Planning and Control Systems. A Framework for Analysis, Division of Research, Harvard Business School, Boston. Google Scholar Arshinder, A. Kanda and S.G. Deshmukh (2008). Supply chain coordination: Perspectives, empirical studies and research directions, International Journal of Production Economics 115, 316– 335. CrossrefWeb of Science®Google Scholar Baker, K.R. and D. Trietsch (2009). Principles of Sequencing and Scheduling, Wiley, Hoboken, NJ. Wiley Online LibraryGoogle Scholar Balakrishnan, A. and F. Vanderbeck (1999). A tactical planning model for mixed-model electronics assembly operations, Operations Research 47, 395– 409. CrossrefWeb of Science®Google Scholar Bard, J.F., R.W. Clayton and T.A. Feo (1994). Machine setup and component placement in printed circuit board assembly, International Journal of Flexible Manufacturing Systems 6, 5– 31. CrossrefGoogle Scholar Barut, S.P. and V. Sridharan (2005). Revenue management in order-driven production systems, Decision Sciences 36(2), 287– 316. Wiley Online LibraryWeb of Science®Google Scholar Basnet, C. and J.M.Y. Leung (2005). Inventory lot-sizing with supplier selection, Computers and Operations Research 32, 1– 14. CrossrefWeb of Science®Google Scholar Berger, P.D., A. Gerstenfeld and A.Z. Zeng (2004). How many suppliers are best? A decision-analysis approach, Omega: The International Journal of Management Science 32(1), 9– 15. CrossrefWeb of Science®Google Scholar Berger, P.D. and A.Z. Zeng (2006). Single versus multiple sourcing in the presence of risks, Journal of the Operational Research Society 57(3), 250– 261. CrossrefWeb of Science®Google Scholar Bertazzi, L. (2003). Rounding off the optimal solution of the economic lot size problem, International Journal of Production Economics 81–82, 385– 392. CrossrefWeb of Science®Google Scholar Bertrand, J.W.M., and H.P.G. van Ooijen (2000). Customer order lead times for production based on lead times and tardiness costs, International Journal of Production Economics 64, 257– 265. CrossrefWeb of Science®Google Scholar Bilge, U. and G. Ulusoy (1995). A time window approach to simultaneous scheduling of machines and material handling system in an FMS, Operations Research 43, 1058– 1070. CrossrefWeb of Science®Google Scholar Blazÿewicz, J., K. Ecker, G. Schmidt and J. Weglarz (1994). Scheduling in Computer and Manufacturing Systems, Springer, Berlin. CrossrefGoogle Scholar Blazÿewicz, J., K. Ecker, E. Pesch, G. Schmidt and J. Weglarz (2007). Handbook on Scheduling. From Theory to Applications, Springer, Berlin. Google Scholar Brah, S.A. and J.L. Hunsucker (1991). Branch and bound algorithm for the flow shop with multiple processors, European Journal of Operational Research 51, 88– 99. CrossrefWeb of Science®Google Scholar Campbell, H.G., R.A. Dudek and M.L. Smith (1970). A heuristic algorithm for the n job, m machine sequencing problem, Management Science 16, B630– B637. CrossrefWeb of Science®Google Scholar Carravilla, M.A. and J. Pinho de Sousa (1995). Hierarchical production planning in a make-to-order company: A case study, European Journal of Operational Research 86, 43– 56. CrossrefWeb of Science®Google Scholar Chahar, K. and K. Taaffe (2009). Risk averse demand selection with all-or-nothing orders, Omega: The International Journal of Management Science 37(5), 996– 1006. CrossrefWeb of Science®Google Scholar Chandra, P. and M.L. Fisher (1994). Coordination of production and distribution planning, European Journal of Operational Research 72(3), 503– 517. CrossrefWeb of Science®Google Scholar Charnsirisaksul, K., P. Griffin and P. Keskinocak (2004). Order selection and scheduling with lead time flexibility, IIE Transactions 36, 697– 707. CrossrefWeb of Science®Google Scholar Chaudhry, S.S., F.G. Forst and J.L. Zydiak (1993). Vendor selection with price breaks, European Journal of Operational Research 70, 52– 66. CrossrefWeb of Science®Google Scholar Chauhan, S.S., V. Gordon and J.-M. Proth (2007). Scheduling in a supply chain environment, European Journal of Operational Research 183(3), 961– 970. CrossrefWeb of Science®Google Scholar Che, Z.H. and H.S. Wang (2008). Supplier selection and supply quantity allocation of common and non-common parts with multiple criteria under multiple products, Computers and Industrial Engineering 55, 110– 133. CrossrefWeb of Science®Google Scholar Chen, C.-Y., Z.-Y. Zhao and M.O. Ball (2001). Quantity and due date quoting available to promise, Information Systems Frontiers 3(4), 477– 488. CrossrefWeb of Science®Google Scholar Chen, D.-S., R.G. Batson and Y. Dang (2010). Applied Integer Programming: Modeling and Solution, Wiley, Hoboken, NJ. Google Scholar Chen, K. and P. Ji (2007). A mixed integer programming model for advanced planning and scheduling (APS), European Journal of Operational Research 181, 515– 522. CrossrefWeb of Science®Google Scholar Chen, Z.-L. (2004). Integrated production and distribution operations: Taxonomy, models and review. In D. Simchi-Levi, S.D. Wu and Z.-J. Shen, Eds., Handbook of Quantitative Supply Chain Analysis: Modeling in the E-Business Era. Kluwer Academic Publishers, Boston, MA. CrossrefGoogle Scholar Chen, Z.-L. and G.L. Vairaktarakis (2005). Integrated scheduling of production and distribution operations, Management Science 51(4), 614– 628. CrossrefWeb of Science®Google Scholar Chen, Z.-L. and G. Pundoor (2006). Order assignment and scheduling in a supply chain, Operations Research 54(3), 555– 572. CrossrefPubMedGoogle Scholar Chen, Z.-L. and N.G. Hall (2007). Supply chain scheduling: Conflict and cooperation in assembly system, Operations Research 55(6), 1072– 1089. CrossrefWeb of Science®Google Scholar Cohen, M.A. and H. Kunreuther (2007). Operations risk management: Overview of Paul Kleindorfer's contributions, Production and Operations Management 16(5), 525– 541. Wiley Online LibraryWeb of Science®Google Scholar Corti, D., A. Pozzetti and M. Zorzini (2006). A capacity-driven approach to establish reliable due dates in MTO environment, International Journal of Production Economics 104, 536– 554. CrossrefWeb of Science®Google Scholar Dauzere-Peres, S. and J.-B. Lasserre (1997). Lot streaming in job-shop scheduling, Operations Research 45(4), 584– 595. CrossrefWeb of Science®Google Scholar Deane, R.H. and S.H. Moon (1992). Work flow control in the flexible flow line, International Journal of Flexible Manufacturing Systems, 8(3–4), 217– 235. CrossrefGoogle Scholar Demirtas, E.A. and O. Ustun (2008). An integrated multiobjective decision making process for supplier selection and order allocation, Omega: The International Journal of Management Science 36, 76– 90. CrossrefWeb of Science®Google Scholar Dolgui, A., B. Finel, N. Guschinsky, G. Levin and F. Vernadat (2006). MIP approach to balancing transfer lines with blocks of parallel operations, IIE Transactions 38, 869– 882. CrossrefWeb of Science®Google Scholar Drexl, A. and A. Kimms (1997). Lotsizing and scheduling—survey and extensions, European Journal of Operational Research 99, 221– 235. CrossrefWeb of Science®Google Scholar Ebben, M.J.R., E.W. Hans and F.M. Olde Weghuis (2005). Workload based acceptance in job shop environments, OR Spectrum 27, 107– 122. CrossrefWeb of Science®Google Scholar Ellis, K.P., F.J. Vittes and J.E. Kobza (2001). Optimizing the performance of a surface mount placement machine, IEEE Transactions on Electronics Packaging Manufacturing 24(3), 160– 170. CrossrefWeb of Science®Google Scholar Erengüc, S.S., N.C. Simpson and A.J. Vakharia (1999). Integrated production/distribution planning in supply chains: An invited review, European Journal of Operational Research, 115, 219– 236. CrossrefWeb of Science®Google Scholar Feo, T.A., J.F. Bard and S.D. Holland (1995). Facility-wide planning and scheduling of printed wiring board assembly, Operations Research 43, 219– 230. CrossrefWeb of Science®Google Scholar Federgruen, A. and Y.-S. Zheng (1995). Efficient algorithms for finding optimal power-of-two policies for production/distribution systems with general setup costs, Operations Research 43, 458– 470. CrossrefWeb of Science®Google Scholar Fourer, R., D.M. Gay and B.W. Kernigham (2003). AMPL, A Modeling Language for Mathematical Programming. Duxbury Press, Pacific Grove, CA. Google Scholar Gallego, G., M. Queyranne and D. Simchi- Levi (1996). Single resource multi-item inventory systems, Operations Research 44, 580– 595. CrossrefWeb of Science®Google Scholar Garey, M.R. and D.S. Johnson (1979). Computers and Intractability: A Guide to the Theory of NP-Completeness. W.H. Freeman, San Francisco. Google Scholar Gershwin, S.B., Y. Dallery, Ch.T. Papadopoulos and J. MacGregor Smith, Eds. (2002). Analysis and Modeling of Manufacturing Systems, Springer, New York. Google Scholar Geunes, J., H.E. Romeijn and K. Taaffe (2006). Requirements planning with pricing and order selection flexibility, Operations Research 54(2), 394– 401. CrossrefWeb of Science®Google Scholar Ghosh, S. and R.J. Gagnon (1989). A comprehensive literature review and analysis of the design, balancing and scheduling of assembly systems, International Journal of Production Research 27, 637– 670. CrossrefWeb of Science®Google Scholar Gotoh, J. and Y. Takano (2007). Newsvendor solutions via conditional value-at-risk minimization, European Journal of Operational Research 179(1), 80– 96. CrossrefWeb of Science®Google Scholar Goyal, S.K. and S.G. Deshmukh (1992). Integrated procurement—production systems: A review, European Journal of Operational Research 62, 1– 10. CrossrefWeb of Science®Google Scholar Goyal, S.K. and S.G. Deshmukh (1997). Integrated procurement-production system in a just-in-time environment—modeling and analysis, Production Planning and Control 8(1), 31– 36. CrossrefWeb of Science®Google Scholar Graves, S.C., H.C. Meal, D. Stefek and A.H. Zeghmi (1983). Scheduling of reentrant flow shops, Journal of Operations Management 3, 197– 207. Wiley Online LibraryGoogle Scholar Greene, J.T. and P.R. Sadowski (1986). A mixed integer program for loading and scheduling multiple flexible manufacturing cells, European Journal of Operational Research 24, 379– 386. CrossrefWeb of Science®Google Scholar Guinet, A.G.P. and A.A. Solomon (1996). Scheduling hybrid flowshops to minimize maximum tardiness or maximum completion time, International Journal of Production Research 34, 1643– 1654. CrossrefWeb of Science®Google Scholar Guschinskaya, O. and A. Dolgui (2010). Comparison of exact and heuristic methods for a transfer line balancing problem, International Journal of Production Economics. 120(2), 276– 286. CrossrefWeb of Science®Google Scholar Güder, F., J.L. Zydiak and S.S. Chaudhry (1995). Non-stationary ordering policies for multi-item inventory systems subject to a single resource constraint, Journal of Operational Research Society 46, 1145– 1152. CrossrefWeb of Science®Google Scholar Güder, F. and J.L. Zydiak (2000). Fixed cycle ordering policies for capacitated multiple item inventory systems with quantity discounts, Computers & Industrial Engineering 38, 67– 77. CrossrefWeb of Science®Google Scholar Hall, N.G., M. Lesaoana and C.N. Potts (2001). Scheduling with fixed delivery dates, Operations Research 49(1), 134– 144. CrossrefWeb of Science®Google Scholar Hall, N.G., M.E. Posner and C.N. Potts (1998a). Scheduling with finite capacity output buffers, Operations Research 46, Suppl. No. 3, S84– S89. CrossrefGoogle Scholar Hall, N.G., M.E. Posner and C.N. Potts (1998b). Scheduling with finite capacity input buffers, Operations Research 46, Suppl. No. 3, S154– S159. CrossrefGoogle Scholar Hall, N.G. and C.N. Potts (2003). Supply chain scheduling: Batching and delivery, Operations Research 51(4), 566– 584. CrossrefPubMedWeb of Science®Google Scholar Harris, F.H. and J.P. Pinder (1995). Revenue management approach to demand management and order booking in assemble-to-order manufacturing, Journal of Operations Management 13(4), 299– 309. Wiley Online LibraryGoogle Scholar Hax, A.C. and H.C. Meal (1975). Hierarchical integration of production planning and scheduling. In M.A. Geisler, Ed., Studies in Management Science, vol. I, Logistics, North Holland, Amsterdam, 53– 69. Google Scholar Hegedus, M.G. and W.J. Hopp (2001). Due date setting with supply constraints in systems using MRP. Computers & Industrial Engineering, 39, 293– 305. CrossrefWeb of Science®Google Scholar Ho, W., X. Xu and K.D. Prasanta (2010). Multi-criteria decision making approaches for supplier evaluation and selection: A literature review, European Journal of Operational Research 202, 16– 24. CrossrefWeb of Science®Google Scholar Hopp, W. and M. Spearman (1996). Factory Physics: Foundations of Manufacturing Management. McGraw-Hill, New York. Google Scholar Hunsucker, J.L. and J.R. Shah (1994). Comparative performance analysis of priority rules in a constrained flow shop with multiple processors environment, European Journal of Operational Research 72, 102– 114. CrossrefWeb of Science®Google Scholar Jackson, P.L., W.L. Maxwell and J.A. Muckstadt (1988). Determining optimal reorder intervals in capacitated production/distribution systems, Management Science 35, 938– 958. CrossrefWeb of Science®Google Scholar Jain, A., M.E. Johnson and E. Safai (1996). Implementation of setup optimization on the shop floor, Operations Research 44, 843– 851. CrossrefWeb of Science®Google Scholar Janak, S.L., C.A. Floudas, J. Kallrath and N. Vormbrock (2006). Production scheduling of a large-scale industrial batch plant. II. Reactive scheduling, Industrial and Engineering Chemistry Research 45(25), 8253– 8269. CrossrefCASWeb of Science®Google Scholar Jayaraman, V., R. Srivastava and W.C. Benton (2006). Supplier selection and order quantity allocation: A comprehensive model, Journal of Supply Chain Management 35(2), 50– 58. Wiley Online LibraryGoogle Scholar Jiang, J. and W. Hsiao (1994). Mathematical programming for the scheduling problem with alternate process plans in FMS, Computers and Industrial Engineering 27(10), 15– 18. CrossrefWeb of Science®Google Scholar Jin, Z.H., K. Ohno, T. Ito and S.E. Elmaghraby (2002). Scheduling hybrid flowshops in printed circuit board assembly lines, Production and Operations Management 11(2), 216– 230. Wiley Online LibraryWeb of Science®Google Scholar Johnson, S.M. (1954). Optimal two- and three-stage production schedules with setup times included, Naval Research Logistics Quarterly 1, 61– 68. Wiley Online LibraryGoogle Scholar Kaczmarczyk, W., T. Sawik, A. Schaller and T.M. Tirpak (2004). Optimal versus heuristic scheduling of surface mount technology lines, International Journal of Production Research 42(10), 2083– 2110. CrossrefWeb of Science®Google Scholar Kaczmarczyk, W., T. Sawik, A. Schaller and T. Tirpak (2006). Production planning and coordination in customer driven supply chains, Wybrane Zagadnienia Logistyki Stosowanej 3, 81– 89. Google Scholar Kasilingam, R.G. and C.P. Lee (1996). Selection of vendors: A mixed-integer programming approach, Computers and Industrial Engineering 31, 347– 350. CrossrefWeb of Science®Google Scholar Kim, Y.-D., H.-G. Lim and M.-W. Park (1996). Search heuristics for a flowshop scheduling problem in a printed circuit board assembly process, European Journal of Operational Research 91, 124– 143. CrossrefWeb of Science®Google Scholar Kimms, A. (1997). Multi-Level Lot Sizing and Scheduling: Methods for Capacitated Dynamic and Deterministic Models. Physica, Heidelberg. CrossrefGoogle Scholar Kis, T. and E. Pesch (2005). A review of exact solution methods for the non-preemptive multiprocessor flowshop problem, European Journal of Operational Research 164(3), 592– 608. CrossrefWeb of Science®Google Scholar Kleindorfer, P.R. and G.H. Saad (2005). Managing disruption risks in supply chains, Production and Operations Management 14(1), 53– 68. Wiley Online LibraryWeb of Science®Google Scholar Kochhar, S. and R.J.T. Morris (1987). Heuristic methods for flexible flow line scheduling, Journal of Manufacturing Systems 6(4), 299– 314. CrossrefWeb of Science®Google Scholar Kolisch, R. (2000). Integration of assembly and fabrication for make-to-order production, International Journal of Production Economics 68, 287– 306. CrossrefWeb of Science®Google Scholar Kouvelis, P. and S. Karabati (1999). Cyclic scheduling in synchronous production lines, IIE Transactions 31(8), 709– 719. CrossrefWeb of Science®Google Scholar Kreipl, S. and J.T. Dickersbach (2008). Scheduling coordination problems in supply chain planning, Annals of Operations Research 106, 103– 122. CrossrefWeb of Science®Google Scholar Kumar, R. and H. Li (1995). Integer programming approach to printed circuit board assembly, IEEE Transactions on Components Packaging and Manufacturing Technology B 18, 720– 727. CrossrefWeb of Science®Google Scholar Kurz, M.E. and R.G. Askin (2004). Scheduling flexible flow lines with sequence-dependent setup times, European Journal of Operational Research 159(1), 66– 82. CrossrefWeb of Science®Google Scholar Kyparisis, G.J. and C. Koulamas (2006). Flexible flowshop scheduling with uniform parallel machines, European Journal of Operational Research 168(3), 985– 997. CrossrefWeb of Science®Google Scholar Lee, C.-Y. and G.L. Vairaktarakis (1994). Minimizing makespan in hybrid flowshops, Operations Research Letters 16, 149– 158. CrossrefWeb of Science®Google Scholar Lee, C.-Y. and Z.-L. Chen (2001), Machine scheduling with transportation considerations, Journal of Scheduling 4, 3– 24. Wiley Online LibraryWeb of Science®Google Scholar Lee, G.-C. and Y.-D. Kim (2004). A branchand- bound algorithm for a two-stage hybrid flowshop scheduling problem minimizing total tardiness, International Journal of Production Research 42(22), 4731– 4743. CrossrefWeb of Science®Google Scholar Lee, W. (2005). A joint economic lot size model for raw material ordering, manufacturing setup, and finished goods delivering, Omega: The International Journal of Management Science 33, 163– 174. CrossrefWeb of Science®Google Scholar Lewis, H.F. and S.A. Slotnick (2002). Multi-period job selection: Planning work loads to maximize profit, Computers & Operations Research 29, 1081– 1098. CrossrefWeb of Science®Google Scholar Li, L. and Z.B. Zabinsky (2009). Incorporating uncertainty into a supplier selection problem, International Journal of Production Economics doi:10.1016/j.ijpe.2009.11.007. Google Scholar Liao, D.-Y., S.-C. Chang, K.W. Pei and C.-M. Chang (1996). Daily scheduling for R&D semiconductor fabrication, IEEE Transactions on Semiconductor Manufacturing 9, 550– 560. CrossrefWeb of Science®Google Scholar Liao, Z. and J. Rittscher (2007). Integration of supplier selection, procurement lot sizing and carrier selection under dynamic demand conditions, International Journal of Production Economics 107, 502– 510. CrossrefWeb of Science®Google Scholar Linn, R. and W. Zhang (1999). Hybrid flowshop scheduling: A survey, Computers & Industrial Engineering 37(1–2), 57– 61. CrossrefWeb of Science®Google Scholar Liu, C.-Y. and S.-C. Chang (2000). Scheduling flexible flow shops with sequence dependent setup effects, IEEE Transactions on Robotics and Automation 16(4), 408– 419. CrossrefWeb of Science®Google Scholar Liu, J. and B.L. MacCarthy (1997). A global MILP model for FMS scheduling, European Journal of Operational Research 100(3), 441– 453. CrossrefWeb of Science®Google Scholar Manne, A.S. (1960). On the job-shop scheduling problem, Operations Research 8, 219– 223. CrossrefWeb of Science®Google Scholar Markland, R.E., K.H. Darby-Dowman and E.D. Minor (1990). Coordinated production scheduling for make-to-order manufacturing, European Journal of Operational Research 45(2–3), 155– 176. CrossrefWeb of Science®Google Scholar Maxwell, W.L. and J.A. Muckstadt (1985). Establishing consistent and realistic reorder intervals in production-distribution systems, Operations Research 33, 1316– 1341. CrossrefWeb of Science®Google Scholar McCormick, S.T., M.L. Pinedo, S. Shenker and B. Wolf (1989). Sequencing in an assembly line with blocking to minimize cycle time, Operations Research 37, 925– 936. CrossrefWeb of Science®Google Scholar Miller, T.C. (2002). Hierarchical Operations in Supply Chain Planning, Springer, London. CrossrefGoogle Scholar Moon, C., Y.H. Lee, C.S. Jeong and J.S. Yun (2008). Integrated process planning and scheduling in a supply chain, Computers and Industrial Engineering 54(4), 1048– 1061. CrossrefWeb of Science®Google Scholar Muckstadt, J.A. (1985). Planning component delivery intervals in constrained assembly systems. In S. Axsäter, Ch. Schneeweiss and E. Silver, Eds., Multi-Stage Production Planning and Inventory Control, Springer, Berlin, 132– 149. Google Scholar Muckstadt, J.A. and R.O. Roundy (1993). Analysis of multistage production systems. In S.C. Graves, A.H.G. Rinnooy Kan and P.H. Zipkin, Eds., Handbooks in Operations Research and Management Science, vol. 4, North-Holland, Amsterdam, 59– 131. Google Scholar Nawaz, M., E.E. Enscore, Jr. and I. Ham (1983). A heuristic algorithm for the m–machine, n–job flow shop sequencing problem, Omega: The International Journal of Management Science 11(1), 91– 95. CrossrefWeb of Science®Google Scholar Nemhauser, G.L. and L.A. Wolsey (1999). Integer and Combinatorial Optimization, John Wiley & Sons, New York. Google Scholar Norrman, A. and U. Jansson (2004). Ericsson's proactive risk management approach after a serious sub-supplier accident, International Journal of Physical Distribution and Logistics Management 34(5), 434– 456. CrossrefGoogle Scholar Nowicki, E. and C. Smutnicki (1996). A fast tabu search algorithm for the permutation flow-shop problem, European Journal of Operational Research 91(1), 160– 175. CrossrefWeb of Science®Google Scholar Nowicki, E. and C. Smutnicki (1998). The flow shop with parallel machines: A tabu search approach, European Journal of Operational Research 106, 226– 253. CrossrefWeb of Science®Google Scholar Oğuz, C., F.S. Salman and Z.B. Yalçin (2010). Order acceptance and scheduling decisions in make-to-order systems, International Journal of Production Economics 125, 200– 211. CrossrefWeb of Science®Google Scholar Örnek, A., S. Özpeynirci and C. Öztürk (2010). A note on “A mixed integer programming model for advanced planning and scheduling (APS),” European Journal of Operational Research 203, 784– 785. CrossrefWeb of Science®Google Scholar Parlar, M. and D. Perry (1996). Inventory models of future supply uncertainty with single and multiple suppliers, Naval Research Logistics 43, 191– 210. Wiley Online LibraryWeb of Science®Google Scholar Pinedo, M. (2005). Planning and Scheduling in Manufacturing and Services. Springer, New York. Google Scholar Pochet, Y. and L.A. Wolsey (2006). Production Planning by Mixed Integer Programming. Springer, Berlin. Google Scholar Quadt, D. and H. Kuhn (2007). A taxonomy of flexible flow line scheduling procedures, European Journal of Operational Research 178(3), 686– 698. CrossrefWeb of Science®Google Scholar Rajendran, C. and D. Chaudhuri (1992). A multistage parallel-processor flowshop problem with minimum flowtime, European Journal of Operational Research 57(1), 111– 122. CrossrefWeb of Science®Google Scholar Rangsaritratsamee, R., W.G. Ferrel and M.B. Kurz (2004). Dynamic rescheduling that simultaneously considers efficiency and stability, Computers and Industrial Engineering 46, 1– 15. CrossrefWeb of Science®Google Scholar Ribas, I., R. Leisten and J.M. Framinan (2010). Review and classification of hybrid flowshop scheduling problems from a production system and a solutions procedure perspective, Computers & Operations Research 37, 1439– 1454. CrossrefWeb of Science®Google Scholar Rockafellar, R.T. and S. Uryasev (2000). Optimization of conditional value-at-risk, Journal of Risk 2(3), 21– 41. CrossrefGoogle Scholar Rockafellar, R.T. and S. Uryasev (2002). Conditional value-at-risk for general loss distributions, Journal of Banking and Finance 26(7), 1443– 1471. CrossrefWeb of Science®Google Scholar Rom, W. and S.A. Slotnick (2009). Order acceptance using genetic algorithms, Computers and Operations Research 36, 1758– 1767. CrossrefWeb of Science®Google Scholar Rosenblatt, M.J. and U.G. Rothblum (1990). On the single resource capacity problem for multi-item inventory system, Operations Research 38, 686– 693. CrossrefWeb of Science®Google Scholar Ruiz, R. and J.A. Vazquez-Rodriguez (2010). The hybrid flow shop scheduling problem, European Journal of Operational Research 205, 1– 18. CrossrefWeb of Science®Google Scholar Ruiz-Torres, A.J. and M. Farzad (2007). The optimal number of suppliers considering the costs of individual supplier failures, Omega: The International Journal of Management Science 35(1), 104– 115. CrossrefWeb of Science®Google Scholar Röslof, J., I. Harjunkoski, J. Björkqvist, S. Karlsson and T. Westerlund (2001). An MILP-based reordering algorithm for complex industrial scheduling and rescheduling, Computers and Chemical Engineering 25, 821– 828. CrossrefCASWeb of Science®Google Scholar Röslof, J., I. Harjunkoski, T. Westerlund and J. Isaksson (2002). Solving a large scale industrial scheduling problem using MILP combined with a heuristic procedure, European Journal of Operational Research 138, 29– 42. CrossrefWeb of Science®Google Scholar Salvador, M.S. (1973). A solution to a special class of flowshop scheduling problems. In S.E. Elmaghraby, Ed., Symposium on the Theory of Scheduling and Its Applications. Berlin: Springer, 83– 91. CrossrefGoogle Scholar Sanayei, A., S.F. Mousavi, M.R. Abdi and A. Mohaghar (2008). An integrated group decision-making process for supplier selection and order allocation using multi-attribute utility theory and linear programming, Journal of the Franklin Institute 345(7), 731– 747. CrossrefWeb of Science®Google Scholar Sarmiento, A.M. and R. Nagi (1999). A review of integrated analysis of production distribution systems, IIE Transactions 31, 1061– 1074. CrossrefWeb of Science®Google Scholar Sarykalin, S., G. Serraino and S. Uryasev (2008). Value-at-risk vs. conditional value-at-risk in risk management and optimization, Tutorials in Operations Research, INFORMS 2008, 270– 294. Google Scholar Sawik, T. (1977). Stochastic optimal control of a multi-facility, multi-product production scheduling with random times of supplies, Control and Cybernetics 6(3–4), 21– 35. Google Scholar Sawik, T. (1990). Modelling and scheduling of a flexible manufacturing system, European Journal of Operational Research 45, 177– 190. CrossrefWeb of Science®Google Scholar Sawik, T. (1993). A scheduling algorithm for flexible flow lines with limited intermediate buffers, Applied Stochastic Models and Data Analysis, Special issue on Manufacturing Systems 9, 127– 138. Wiley Online LibraryWeb of Science®Google Scholar Sawik, T. (1994). New algorithms for scheduling flexible flow lines. In Proceedings of Japan-U.S.A. Symposium on Flexible Automation. Kobe, July 11–18, 3, 1091– 1096. Google Scholar Sawik, T. (1995a). Integer programming models for the design and balancing of flexible assembly systems, Mathematical and Computer Modelling 21(4), 1– 12. CrossrefWeb of Science®Google Scholar Sawik, T. (1995b). Scheduling flexible flow lines with no in-process buffers, International Journal of Production Research 33, 1359– 1370. CrossrefWeb of Science®Google Scholar Sawik, T. (1996). A multilevel machine and vehicle scheduling in a flexible manufacturing system, Mathematical & Computer Modelling 23(7), 45– 57. CrossrefWeb of Science®Google Scholar Sawik, T. (1998a). A lexicographic approach to bi-objective loading of a flexible assembly system, European Journal of Operational Research 107(3), 658– 668. CrossrefWeb of Science®Google Scholar Sawik, T. (1998b). Simultaneous loading, routing and assembly plan selection in a flexible assembly system, Mathematical and Computer Modelling 28(9), 19– 29. CrossrefWeb of Science®Google Scholar Sawik, T. (1999). Production Planning and Scheduling in Flexible Assembly Systems, Springer-Verlag, Berlin. CrossrefGoogle Scholar Sawik, T. (2000a). Mixed integer programming for scheduling flexible flow lines with limited intermediate buffers, Mathematical and Computer Modelling 31, 39– 52. CrossrefWeb of Science®Google Scholar Sawik, T. (2000b). Simultaneous versus sequential loading and scheduling of flexible assembly systems, International Journal of Production Research 38, 3267– 3282. CrossrefWeb of Science®Google Scholar Sawik, T. (2000c). An LP-based approach for loading and routing in a flexible assembly line, International Journal of Production Economics 64(1–3), 49– 58. CrossrefWeb of Science®Google Scholar Sawik, T. (2001). Mixed integer programming for scheduling surface mount technology lines, International Journal of Production Research 39, 3219– 3235. CrossrefWeb of Science®Google Scholar Sawik, T. (2002a). Balancing and scheduling of surface mount technology lines, International Journal of Production Research 40(9), 1973– 1991. CrossrefWeb of Science®Google Scholar Sawik, T. (2002b). Monolithic vs. hierarchical balancing and scheduling of a flexible assembly line, European Journal of Operational Research 143(1), 115– 124. CrossrefWeb of Science®Google Scholar Sawik, T. (2002c). An exact approach for batch scheduling in flexible flow lines with limited intermediate buffers, Mathematical and Computer Modelling 36, 461– 471. CrossrefWeb of Science®Google Scholar Sawik, T. (2004). Loading and scheduling of a flexible assembly system by mixed integer programming, European Journal of Operational Research 154(1), 1– 19. CrossrefWeb of Science®Google Scholar Sawik, T. (2005a). Integer programming approach to production scheduling for make-to-order manufacturing, Mathematical and Computer Modelling 41(1), 99– 118. CrossrefWeb of Science®Google Scholar Sawik, T. (2005b). A cyclic versus flexible approach to materials ordering in make-toorder assembly, Mathematical and Computer Modelling 42(3–4), 279– 290. CrossrefWeb of Science®Google Scholar Sawik, T. (2006). Hierarchical approach to production scheduling in make-to-order assembly, International Journal of Production Research 44(4), 801– 830. CrossrefWeb of Science®Google Scholar Sawik, T. (2007a). A multi-objective customer orders assignment and resource leveling in make-to-order manufacturing, International Transactions in Operational Research 14(6), 491– 508. Wiley Online LibraryGoogle Scholar Sawik, T. (2007b). Multi-objective master production scheduling in make-to-order manufacturing, International Journal of Production Research 45(12), 2629– 2653. CrossrefWeb of Science®Google Scholar Sawik, T. (2007c). A lexicographic approach to bi-objective scheduling of single-period orders in make-to-order manufacturing, European Journal of Operational Research 180(3), 1060– 1075. CrossrefWeb of Science®Google Scholar Sawik, T. (2007d). Integer programming approach to reactive scheduling in maketo- order manufacturing, Mathematical and Computer Modelling 46(11–12), 1373– 1387. CrossrefWeb of Science®Google Scholar Sawik, T. (2009a). Multi-objective due-date setting in a make-to-order environment, International Journal of Production Research 47(22), 6205– 6231. CrossrefWeb of Science®Google Scholar Sawik, T. (2009b). Monolithic versus hierarchical approach to integrated scheduling in a supply chain, International Journal of Production Research 47(21), 5881– 5910. CrossrefWeb of Science®Google Scholar Sawik, T. (2009c). Coordinated supply chain scheduling, International Journal of Production Economics 120(2), 437– 451. CrossrefWeb of Science®Google Scholar Sawik, T. (2010a). Single vs. multiple objective supplier selection in a make to order environment, Omega: The International Journal of Management Science 38(3–4), 203– 212. CrossrefWeb of Science®Google Scholar Sawik, T. (2010b). A bi-objective supply chain scheduling. In K.D. Lawrence, R.K. Klimberg and V.M. Miori, Eds., The Supply Chain in Manufacturing, Distribution, and Transportation: Modeling, Optimization, and Applications. CRC Press, Boca Raton, FL. Google Scholar Sawik, T. (2011a). Selection of supply portfolio under disruption risks, Omega: The International Journal of Management Science 39(2), 194– 208. CrossrefWeb of Science®Google Scholar Sawik, T. (2011b). Selection of a dynamic supply portfolio in make-to-order environment with risks, Computers & Operations Research 38(4), 782– 796. CrossrefWeb of Science®Google Scholar Sawik, T., A. Schaller and T.M. Tirpak (2000). Issues in loading and scheduling of SMT lines, Zeszyty Naukowe Politechniki Ślaskiej, Automatyka, no. 129, 331– 341. Google Scholar Sawik, T., A. Schaller and T.M. Tirpak (2002). Scheduling of printed wiring board assembly in surface mount technology lines, Journal of Electronics Manufacturing, special issue on Production Planning and Scheduling in Electronics Manufacturing 11(1), 1– 17. Web of Science®Google Scholar Schmidt, G. (2000). Scheduling with limited machine availability, European Journal of Operational Research 121, 1– 15. CrossrefWeb of Science®Google Scholar Schneeweiss, Ch. (1999). Hierarchies in Distributed Decision Making, Springer- Verlag, Berlin. CrossrefGoogle Scholar Schneeweiss, Ch. and K. Zimmer (2004). Hierarchical coordination mechanism within the supply chain, European Journal of Operational Research 154, 687– 703. CrossrefWeb of Science®Google Scholar Scholl, A. (1999). Balancing and Sequencing of Assembly Lines. Physica-Verlag, Heidelberg. CrossrefGoogle Scholar Shanthikumar, J.G., D.D. Yao, W. Henk and M. Zijm, Eds. (2003). Stochastic Modeling and Optimization of Manufacturing Systems and Supply Chains. Springer, New York. CrossrefGoogle Scholar Shapiro, J.F. (1993). Mathematical programming models and methods for production planning and scheduling. In S.C. Graves, A.H.G. Rinnooy Kan and P.H. Zipkin, Eds., Handbook in Operations Research and Management Science: Logistics of Production and Inventory. North-Holland, Amsterdam. Google Scholar Shapiro, J.F. (2001). Modeling the Supply Chain. Duxbury Press, Pacific Grove, CA. Google Scholar Sheffi, Y. (2005). The Resilient Enterprise. MIT Press, Cambridge, MA. Google Scholar Silver, E.A., D.F. Pyke and R. Petersen (1998). Inventory Management and Production Planning and Scheduling. John Wiley & Sons, New York. Google Scholar Slotnick, S.A. and T.E. Morton (1996). Selecting jobs for a heavily loaded shop with lateness penalties, Computers & Operations Research 23(2), 131– 140. CrossrefWeb of Science®Google Scholar Slotnick, S.A. and T.E. Morton (2007). Order acceptance with weighted tardiness, Computers and Operations Research 34(10), 3029– 3042. CrossrefWeb of Science®Google Scholar Smith, S.F. (1995). Reactive scheduling systems, In D.E. Brown and W.T. Scherer, Eds., Intelligent Scheduling Systems. Kluwer Academic Publishers, Boston, 155– 192. CrossrefGoogle Scholar Stadtler, H. (2005). Supply chain management and advanced planning—basics, overview and challenges, European Journal of Operational Research 163, 575– 588. CrossrefWeb of Science®Google Scholar Steuer, R.E. (1986). Multiple Criteria Optimization: Theory, Computation, and Applications. John Wiley & Sons, New York. Google Scholar Sun, D. and D. Atkins (1997). 98%— effective lot-sizing for assembly inventory systems with backlogging, Operations Research 45, 940– 951. CrossrefWeb of Science®Google Scholar Sun, J. and D. Xue (2001). A dynamic reactive scheduling mechanism for responding to changes of production orders and manufacturing resources, Computers in Industry 46, 189– 207. CrossrefWeb of Science®Google Scholar Talluri, K.T. and G.J. van Ryzin (2004). The Theory and Practice of Revenue Management. Kluwer Academic Publishers, Boston. CrossrefGoogle Scholar Tang, C.S. (2006). Perspectives in supply chain risk management, International Journal of Production Economics 103, 451– 488. CrossrefWeb of Science®Google Scholar Tempelmeier, H. and M.C. Derstroff (1996). A Lagrangian-based heuristic for dynamic multi-level, multi-item constrained lot sizing with setup times, Management Science 42(5), 738– 747. CrossrefWeb of Science®Google Scholar Thomas, D.J. and P.M. Griffin (1996). Coordinated supply chain management, European Journal of Operational Research 94(1), 1– 15. CrossrefWeb of Science®Google Scholar Tirpak, T.M. (2000). Design-to-manufacturing information management for electronics assembly, International Journal of Flexible Manufacturing Systems 12(2), 189– 205. CrossrefWeb of Science®Google Scholar Tseng, F.T., E.F. Stafford, Jr. and J.N.D. Gupta (2004). An empirical analysis of integer programming formulations for the permutation flowshop. Omega: The International Journal of Management Science 32, 285– 293. CrossrefWeb of Science®Google Scholar Ulusoy, G. and U. Bilge (1993). Simultaneous scheduling of machines and automated guided vehicles, International Journal of Production Research 31, 2857– 2873. CrossrefWeb of Science®Google Scholar Uryasev, S. (2000). Conditional value-at-risk: Optimization algorithms and applications, Financial Engineering News 14, February, 1– 5. Google Scholar Ustun, O. and E.A. Demirtas (2008). An integrated multi-objective decision making process for multi-period lot sizing with supplier selection, Omega: The International Journal of Management Science 36, 509– 521. CrossrefWeb of Science®Google Scholar Van der Vaart, T. and D.P. Van Donk (2008). A critical review of survey-based research in supply chain integration, International Journal of Production Economics 111, 42– 55. CrossrefWeb of Science®Google Scholar Vieira, G.E., J.W. Herrman and E. Lin (2003). Rescheduling manufacturing systems: A framework of strategies, policies and methods, Journal of Scheduling 6(1), 39– 62. CrossrefWeb of Science®Google Scholar Vignier, A., J.C. Billaut and C. Proust (1999). Hybrid flowshop scheduling problems: State of the art, Rairo-Recherche Operationnelle—Operations Research 33(2), 117– 183. CrossrefWeb of Science®Google Scholar Voss, S. and D.L. Woodruff (2003). Introduction to Computational Optimization Models for Production Planning in a Supply Chain, Springer- Verlag, Berlin. CrossrefGoogle Scholar Wagner, H.M. (1959). An integer linearprogramming model for machine scheduling, Naval Research Logistics Quarterly 6, 131– 140. Wiley Online LibraryGoogle Scholar Wang, H. (2005). Flexible flowshop scheduling: Optimum, heuristics and artificial intelligence solutions, Expert Systems 22(2), 78– 85. Wiley Online LibraryCASWeb of Science®Google Scholar Wang, W., P.C. Nelson and T.M. Tirpak (2000). Optimization of high-speed multistation SMT placement machines using evolutionary algorithms, IEEE Transactions on Electronics Packaging Manufacturing 22(2), 137– 146. CrossrefGoogle Scholar Weber, C.A. and J.R. Current (1993). A multiobjective approach to vendor selection, European Journal of Operational Research 68, 173– 184. CrossrefWeb of Science®Google Scholar Wester, F.A.W., J. Wijngaard and W.H.M. Zijm (1992). Order acceptance strategies in a production-to-order environment with setup times and due dates, International Journal of Production Research 30(4), 1313– 1326. CrossrefWeb of Science®Google Scholar Wilson, J.M. (1989). Alternative formulations of a flow-shop scheduling problem, Journal of the Operational Research Society 40, 395– 399. CrossrefWeb of Science®Google Scholar Wittrock, R.J. (1985). Scheduling algorithms for flexible flow lines, IBM Journal of Research and Development 29, 401– 412. CrossrefWeb of Science®Google Scholar Wittrock, R.J. (1988). An adaptable scheduling algorithm for flexible flow lines, Operations Research 36, 445– 453. CrossrefWeb of Science®Google Scholar Wolsey, L.A. (1998). Integer Programming, John Wiley & Sons, New York. Google Scholar Wu, D. and D.L. Olson (2008). Supply chain risk, simulation, and vendor selection, International Journal of Production Economics 114, 646– 655. CrossrefWeb of Science®Google Scholar Xia, W. and Z. Wu (2007). Supplier selection with multiple criteria in volume discount environments, Omega: The International Journal of Management Science 35, 494– 504. CrossrefWeb of Science®Google Scholar Yu, H., A.Z. Zeng and L. Zhao (2009). Single or dual sourcing: Decision-making in the presence of supply chain disruption risks, Omega: The International Journal of Management Science 37, 788– 800. CrossrefWeb of Science®Google Scholar Yue, J., Y. Xia and T. Tran (2010). Selecting sourcing partners for a make-to-order supply chain, Omega: The International Journal of Management Science 38(3–4), 136– 144. CrossrefWeb of Science®Google Scholar Zipkin, P.H. (2000). Foundations of Inventory Management, McGraw-Hill, New York. Google Scholar Zorzini, M., D. Corti and A. Pozzetti (2008). Due date (DD) quotation and capacity planning in make-to-order companies: Results from an empirical analysis, International Journal of Production Economics 112, 919– 933. CrossrefWeb of Science®Google Scholar Scheduling in Supply Chains Using Mixed Integer Programming ReferencesRelatedInformation" @default.
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• W4205557572 date "2011-05-13" @default.
• W4205557572 modified "2023-10-13" @default.
• W4205557572 title "References" @default.
• W4205557572 cites W1483746956 @default.
• W4205557572 cites W1488806426 @default.
• W4205557572 cites W1499199352 @default.
• W4205557572 cites W1520336569 @default.
• W4205557572 cites W1647779468 @default.
• W4205557572 cites W181763844 @default.
• W4205557572 cites W1964092764 @default.
• W4205557572 cites W1965397541 @default.
• W4205557572 cites W1968714144 @default.
• W4205557572 cites W1969573629 @default.
• W4205557572 cites W1970329178 @default.
• W4205557572 cites W1970483372 @default.
• W4205557572 cites W1971489618 @default.
• W4205557572 cites W1971998894 @default.
• W4205557572 cites W1972323916 @default.
• W4205557572 cites W1974403532 @default.
• W4205557572 cites W1974441729 @default.
• W4205557572 cites W1974530962 @default.
• W4205557572 cites W1975533380 @default.
• W4205557572 cites W1975602051 @default.
• W4205557572 cites W1976951442 @default.
• W4205557572 cites W1978900640 @default.
• W4205557572 cites W1980760279 @default.
• W4205557572 cites W1981212236 @default.
• W4205557572 cites W1981342995 @default.
• W4205557572 cites W1983412100 @default.
• W4205557572 cites W1983990433 @default.
• W4205557572 cites W1984297368 @default.
• W4205557572 cites W1986963033 @default.
• W4205557572 cites W1988115142 @default.
• W4205557572 cites W1992109799 @default.
• W4205557572 cites W1993809051 @default.
• W4205557572 cites W1994430594 @default.
• W4205557572 cites W1995313677 @default.
• W4205557572 cites W1995632573 @default.
• W4205557572 cites W1996754234 @default.
• W4205557572 cites W1996757985 @default.
• W4205557572 cites W1998895018 @default.
• W4205557572 cites W1998966479 @default.
• W4205557572 cites W2000056497 @default.
• W4205557572 cites W2001415172 @default.
• W4205557572 cites W2001682762 @default.
• W4205557572 cites W2001721457 @default.
• W4205557572 cites W2001887384 @default.
• W4205557572 cites W2002130588 @default.
• W4205557572 cites W2003074920 @default.
• W4205557572 cites W2003267429 @default.
• W4205557572 cites W2005329159 @default.
• W4205557572 cites W2007203426 @default.
• W4205557572 cites W2007515360 @default.
• W4205557572 cites W2007755855 @default.
• W4205557572 cites W2007797237 @default.
• W4205557572 cites W2009453241 @default.
• W4205557572 cites W2009744457 @default.
• W4205557572 cites W2011151328 @default.
• W4205557572 cites W2012076552 @default.
• W4205557572 cites W2013285825 @default.
• W4205557572 cites W2013463306 @default.
• W4205557572 cites W2013777142 @default.
• W4205557572 cites W2014168449 @default.
• W4205557572 cites W2014204963 @default.
• W4205557572 cites W2014691041 @default.
• W4205557572 cites W2016236059 @default.
• W4205557572 cites W2016253214 @default.
• W4205557572 cites W2018028283 @default.
• W4205557572 cites W2018545447 @default.
• W4205557572 cites W2019704988 @default.
• W4205557572 cites W2022151531 @default.
• W4205557572 cites W2022190018 @default.
• W4205557572 cites W2022369810 @default.
• W4205557572 cites W2022864263 @default.
• W4205557572 cites W2024085737 @default.
• W4205557572 cites W2024274253 @default.
• W4205557572 cites W2027035110 @default.
• W4205557572 cites W2027507546 @default.
• W4205557572 cites W2027725385 @default.
• W4205557572 cites W2029215259 @default.
• W4205557572 cites W2030377031 @default.
• W4205557572 cites W2031232442 @default.
• W4205557572 cites W2031318077 @default.
• W4205557572 cites W2031400698 @default.
• W4205557572 cites W2032448387 @default.
• W4205557572 cites W2033470947 @default.
• W4205557572 cites W2034286063 @default.
• W4205557572 cites W2035133691 @default.
• W4205557572 cites W2035617138 @default.
• W4205557572 cites W2035986265 @default.
• W4205557572 cites W2036480243 @default.
• W4205557572 cites W2037246711 @default.
• W4205557572 cites W2038416734 @default.
• W4205557572 cites W2039686757 @default.
• W4205557572 cites W2039771670 @default.
• W4205557572 cites W2040344278 @default.

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