Help
Cart
Skip main navigation

Available Issues

April 10, 2013 - May 26, 2026

Available Issues

April 10, 2013 - May 26, 2026

A Review of Operations Research in Mine Planning

Published Online:7 Apr 2010https://doi.org/10.1287/inte.1090.0492

References

  • Akaike A., Dagdelen K., Dardano C., Francisco M., Proud J. A strategic production scheduling method for an open pit mine. Proc. 28th Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos., (1999) (SME, Littleton, CO) 729–738Google Scholar
  • Alarie S., Gamache M. Overview of solution strategies used in truck dispatching systems for open pit mines. Internat. J. Surface Mining Reclamation Environ. (2002) 16(1):59–76CrossrefGoogle Scholar
  • Alford C. Optimization in underground mine design. Proc. 25th Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos. (1995) (AusIMM, Brisbane, Australia) 213–218Google Scholar
  • Amaya J., Espinoza D., Goycoolea M., Moreno E., Prevost T., Rubio E. A scalable approach to optimal block scheduling. Proc. 35th Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos. (2010) Vancouver(CIM, Montréal) . ForthcomingGoogle Scholar
  • Askari-Nasab H., Frimpong S., Szymanski J. Modeling open pit dynamics using discrete simulation. Internat. J. Mining Reclamation Environ. (2007) 21(1):35–49CrossrefGoogle Scholar
  • Baker W. R., Daellenbach H. G. Two-phase optimization of coal strategies at a power station. Eur. J. Oper. Res. (1984) 18(3):304–314CrossrefGoogle Scholar
  • Barbaro R., Ramani R. Generalized multiperiod MIP model for production scheduling and processing facilities selection and location. Mining Engrg. (1986) 38(2):107–114Google Scholar
  • Bienstock D., Zuckerberg M. Solving LP relaxations of large-scale precedence constrained problems. Proc. 14th Conf. Integer Programming Combin. Optim. (IPCO 2010) (2010) (Springer, Berlin) Lecture Notes in Computer ScienceForthcomingCrossrefGoogle Scholar
  • Binkowski M., McCarragher B. A queuing model for the design and analysis of a mining stockyard. Discrete Event Dynamic Systems: Theory and Applications (1999) (Kluwer Academic Publishers, Boston) 75–98chapter 9Google Scholar
  • Bixby R., Rothberg E. Progress in computational mixed integer programming—a look back from the other side of the tipping point. Ann. Oper. Res. (2007) 149(1):37–41CrossrefGoogle Scholar
  • Bley A., Boland N., Fricke C., Froyland G. A strengthened formulation and cutting planes for the open pit mine production scheduling problem. Comput. Oper. Res. (2010) 37(9):1641–1647CrossrefGoogle Scholar
  • Bley A., Gleixner A. M., Koch T., Vigerske S. Comparing MIQCP solvers to a specialised algorithm for mine production scheduling. (2009) . ZIB Report 09-32, ZIB, Berlin. Retrieved January 1, 2010, http://opus.kobv.de/zib/volltexte/2009/1206/Google Scholar
  • Boland N., Dumitrescu I., Froyland G. A multistage stochastic programming approach to open pit mine production scheduling with uncertain geology. (2010) . Working paper. Retrieved January 20, 2010, http://www.optimization-online.org/DB_FILE/2008/10/2123.pdfGoogle Scholar
  • Boland N., Dumitrescu I., Froyland G., Gleixner A. M. LP-based disaggregation approaches to solving the open pit mining production scheduling problem with block processing selectivity. Comput. Oper. Res. (2009) 36(4):1064–1089CrossrefGoogle Scholar
  • Bradley C. E., Taylor S. G., Gray W. I. Sizing storage facilities for open pit coal mines. IIE Trans. (1985) 17(4):320–326CrossrefGoogle Scholar
  • Brazil M., Thomas D. A. Network optimization for the design of underground mines. Networks (2007) 49(1):40–50CrossrefGoogle Scholar
  • Brazil M., Lee D. H., Van Leuven M., Rubinstein J. H., Thomas D. A., Wormald N. C. Optimising declines in underground mines. Mining Tech.: IMM Trans. Sect. A (2003) 112(3):A164–A170CrossrefGoogle Scholar
  • Brennan M. J., Schwartz E. S. Evaluating natural resource investments. J. Bus. (1985) 58(2):135–157CrossrefGoogle Scholar
  • Burt C., Caccetta L., Hill S., Welgama P., Zerger A., Argent R. M. Models for mining equipment selection. MODSIM 2005 Internat. Congress Modeling Simulation (2005) (Modelling and Simulation Society of Australia and New Zealand)1730–1736Google Scholar
  • Busnach E., Mehrez A., Sinuany-Stern Z. A production problem in phosphate mining. J. Oper. Res. Soc. (1985) 36(4):285–288CrossrefGoogle Scholar
  • Caccetta L., Hill S. P. An application of branch and cut to open pit mine scheduling. J. Global Optim. (2003) 27(2–3):349–365CrossrefGoogle Scholar
  • Cai W., Xie H., Wang Y., Jiang Y. Design of open-pit phases with consideration of schedule constraints. Proc. 29th Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos. (2001) (CUMT, Beijing) 217–221Google Scholar
  • Carlyle W. M., Eaves B. C. Underground planning at Stillwater Mining Company. Interfaces (2001) 31(4):50–60LinkGoogle Scholar
  • Caro R., Epstein R., Santibañez P., Weintraub A., Weintraub A., Romero C., Bjorndal T., Epstein R. An integrated approach to the long-term planning process in the copper mining industry. Handbook of Operations Research in Natural Resources (2007) (Springer, New York) 595–609CrossrefGoogle Scholar
  • Carvallo F., Alonso A., Escudero L., Guignard-Spielberg M., Weintraub A. Lagrangian relaxation decomposes a stochastic mining problem. (2009) . Working Paper 11, Institute Milenium Complex Engineering Systems, Santiago, ChileGoogle Scholar
  • Chanda E. K. C. An application of integer programming and simulation to production planning for a stratiform ore body. Mining Sci. Tech. (1990) 11(2):165–172CrossrefGoogle Scholar
  • Chen J., Gu D., Li J. Optimization principle of combined surface and underground mining and its applications. J. Central South Univ. Tech. (China) (2003) 10(3):222–225CrossrefGoogle Scholar
  • Chicoisne R., Espinoza D., Goycoolea M., Moreno E., Rubio E. A new algorithm for the open-pit mine scheduling problem. (2009) . Working paper, Universidad Adolfo Ibañez and Universidad de Chile, SantiagoGoogle Scholar
  • Cortazar G., Schwartz E. S., Salinas M. Evaluating environmental investments: A real options approach. Management Sci. (1998) 44(8):1059–1070LinkGoogle Scholar
  • Dagdelen K., Johnson T. Optimum open pit mine production scheduling by Lagrangian parameterization. Proc. 19th Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos. (1986) (SME, Littleton, CO) 127–141Google Scholar
  • Datamine NPV scheduler. (2009) (Bedfordshire, UK). http://www.datamine.co.uk/products/PDF_Flyers/NPVScheduler4_LoRes_Sep07_LoRes_English.pdfGoogle Scholar
  • Denby B., Schofield D. Open-pit design and scheduling by use of genetic algorithms. Mining Tech.: IMM Trans. Sect. A (1994) 103:A21–A26Google Scholar
  • Deutsch C. The place of geostatistical simulation in resource/reserve estimation. Proc. Internat. Conf. Mining Innovation (MININ) (2004) University of Chile and the Catholic University of Chile, SantiagoGoogle Scholar
  • Dijkstra E. W. A note on two problems in connection with graphs. Numerische Mathematik (1959) 1(1):269–271CrossrefGoogle Scholar
  • Dornetto L. D. An adaptive control scheme—expert system—that optimizes the operation of a proposed underground coal mining system with applications to shortwall, longwall and room pillar mining systems. Proc. 1988 IEEE Internat. Conf. Systems Man, Cybernetics. (1988) (International Academic Publishers, Pergamon Press, Beijing) 209–214CrossrefGoogle Scholar
  • Dowd P., Onur A. Open-pit optimization, part 1: Optimal open-pit design. Mining Tech.: IMM Trans. Sect. A (1993) 102:A95–A104Google Scholar
  • Elevli B. Open pit mine design and extraction sequencing by use of OR and AI concepts. Internat. J. Surface Mining Reclamation Environ. (1995) 9(4):149–153CrossrefGoogle Scholar
  • Epstein R., Gaete S., Caro F., Weintraub A., Santibañez P., Catalan J. Optimizing long term planning for underground copper mines. Proc. Copper 2003-Cobre 2003, 5th Internat. Conf. (2003) I(CIM and the Chilean Institute of Mining, Santiago, Chile) 265–279Google Scholar
  • Erarslan K., Çelebi N. A simulative model for optimum pit design. CIM Bull. (2001) 94(1055):59–68Google Scholar
  • Everett J., Brebbia C. A., Zannetti P. Reducing the environmental and economic costs of handling iron ore. Proc. Internat. Conf. Development Appl. Comput. Techniques Environ. Stud. VI (1996) Como, Italy:573–582Google Scholar
  • Frimpong S., Asa E., Szymanski J. Intelligent modeling: Advances in open pit mine design and optimization research. Internat. J. Surface Mining Reclamation Environ. (2002) 16(2):134–143CrossrefGoogle Scholar
  • Fytas K., Hadjigeorgiou J., Collins J. L. Production scheduling optimization in open pit mines. Internat. J. Surface Mining Reclamation Environ. (1993) 7(1):1–9CrossrefGoogle Scholar
  • Fytas K., Pelley C., Calder P. Optimization of open pit short- and long-range production scheduling. CIM Bull. (1987) 80(904):55–61Google Scholar
  • Gamache M., Grimard R., Cohen P. A shortest-path algorithm for solving the fleet management problem in underground mines. Eur. J. Oper. Res. (2005) 166(2):497–506CrossrefGoogle Scholar
  • Gemcom Gemcom Software International: MineSched. (2009) (Vancouver). http://www.gemcomsoftware.com/products/MineSched/Google Scholar
  • Gershon M. Heuristic approaches for mine planning and production scheduling. Internat. J. Mining Geological Engrg. (1987) 5(1):1–13CrossrefGoogle Scholar
  • Gershon M., Murphy F. Optimizing single hole mine cuts by dynamic programming. Eur. J. Oper. Res. (1989) 38(1):56–62CrossrefGoogle Scholar
  • Gholamnejad J., Osanloo M. Using chance constrained binary integer programming in optimizing long term production scheduling for open pit mine design. Mining Tech.: IMM Trans. Sect. A (2007) 116(2):58–66CrossrefGoogle Scholar
  • Gleixner A. M. Solving large-scale open pit mining production scheduling problems by integer programming. (2008) . Master's thesis, Technische Universität Berlin, Berlin. http://opus.kobv.de/zib/volltexte/2009/1187/Google Scholar
  • Goodman G. V. R., Sarin S. C. Using mathematical programming to develop optimal overburden transport strategies in a surface coal mining operation. Internat. J. Surface Mining Reclamation Environ. (1988) 2(1):51–58CrossrefGoogle Scholar
  • Gregory C. E.A Concise History of Mining (1980) (Pergamon, Oxford, UK) Google Scholar
  • Grieco N., Dimitrakopoulos R. Managing grade risk in stope design optimization: Probabilistic mathematical programming model and application in sublevel stoping. Mining Tech.: IMM Trans. Sect. A (2007) 116(2):49–57CrossrefGoogle Scholar
  • Halatchev R., Ganguli R., Dessureault S., Kecojevic V., Dwyer J. A model of discounted profit variation of open pit production sequencing optimization. Proc. 32nd Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos. (2005) (SME, Littleton, CO) 315–323CrossrefGoogle Scholar
  • Hamrin H., Hustrulid W. A., Bullock R. L. Underground mining methods and applications. Underground Mining Methods: Engineering Fundamentals and International Case Studies (2001) (SME, Littleton, CO) 3–14Google Scholar
  • Hochbaum D. S., Chen A. Performance analysis and best implementations of old and new algorithms for the open-pit mining problem. Oper. Res. (2000) 48(6):894–914LinkGoogle Scholar
  • Hoerger S., Hoffman L., Seymour F. Mine planning at Newmont's Nevada operations. Mining Engrg. (1999) 51(10):26–30Google Scholar
  • Huang Y., Kumar U. Optimizing the number of load-haul-dump machines in a Swedish mine by using queuing theory—A case study. Internat. J. Surface Mining Reclamation Environ. (1994) 8(4):171–174CrossrefGoogle Scholar
  • IBM ILOG CPLEX. (2009) (Incline Village, NV). http://www-01.ibm.com/software/integration/optimization/cplexGoogle Scholar
  • Jalali S. E., Ataee-pour M., Shahriar K. Pit limits optimization using a stochastic process. CIM Magazine (2006) 1(6):90Google Scholar
  • Jawed M., Elbrond J., Tang X. Optimal production planning in underground coal mines through goal programming: A case study from an Indian mine. Proc. 24th Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos. (1993) (CIM, Montréal) 44–50Google Scholar
  • Kappas G., Yegulalp T. An application of closed queueing networks theory in truck-shovel systems. Internat. J. Surface Mining Reclamation Environ. (1991) 5(1):45–53CrossrefGoogle Scholar
  • Kawahata K. A new algorithm to solve large scale mine production scheduling problems by using the Lagrangian relaxation method. (2006) . Doctoral thesis, Colorado School of Mines, GoldenGoogle Scholar
  • Kim Y., Zhao Y. Optimum open pit production sequencing—The current state of the art. Proc. Preprint Soc. Mining Metallurgy Exploration Ann. Meeting, (1994) (SME, Littleton, CO) Google Scholar
  • Klingman D., Phillips N. Integer programming for optimal phosphate-mining strategies. J. Oper. Res. Soc. (1988) 39(9):805–810CrossrefGoogle Scholar
  • Krige D. G. A statistical approach to some basic mine valuation problems on the Witwatersrand. J. Chemical Metallurgical Mining Soc. South Africa (1951) 52(6):119–139Google Scholar
  • Kuchta M., Newman A., Topal E. Implementing a production schedule at LKAB's Kiruna Mine. Interfaces (2004) 34(2):124–134LinkGoogle Scholar
  • Kumral M. Reliability-based optimisation of a mine production system using genetic algorithms. J. Loss Prevention Process Indust. (2005) 18(3):186–189CrossrefGoogle Scholar
  • Lane K.The Economic Definition of Ore: Cutoff Grade in Theory and Practice (1988) (Mining Journal Books Limited, London) Google Scholar
  • Laurich R., Kennedy B. Planning and design of surface mines. Surface Mining (1990) (Port City Press, Baltimore) 465–469chapter 5.2Google Scholar
  • Lemelin B., Abdel Sabour S. A., Poulin R., Magri E. An integrated evaluation system for mine planning under uncertainty. Proc. 33rd Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos. (2007) (Gecamin Ltda., Santiago, Chile) 262–269Google Scholar
  • Lerchs H., Grossmann I. Optimum design of open-pit mines. Canadian Mining Metallurgical Bull. (1965) 58:17–24Google Scholar
  • Lindo LINGO optimization software. . Accessed March 17, 2010, http://www.lindo.com/index.php?option=com_content&view=article&id=136&Itemid=54Google Scholar
  • Lizotte Y., Elbrond J. Optimal layout of underground mining levels. CIM Bull. (1985) 78(873):41–48Google Scholar
  • Magda R. Mathematical model for estimating the economic effectiveness of production process in coal panels and an example of its practical application. Internat. J. Prod. Econom. (1994) 34(1):47–55CrossrefGoogle Scholar
  • Maptek (2009) (Maptek Software Pty Ltd. Vulcan Chronos, Sydney, Australia) . http://maptek.com/products/vulcan/scheduling/chronos_reserving_scheduling_module.htmlGoogle Scholar
  • McKenzie P., Newman A. M., Tenorio L. Front Range Aggregates optimizes feeder movements at its quarry. Interfaces (2008) 38(6):436–447LinkGoogle Scholar
  • McNearny R., Nie Z. Simulation of a conveyor belt network at an underground coal mine. Mineral Resources Engrg. (2000) 9(3):343–355CrossrefGoogle Scholar
  • MineMax (2006) (MineMax Software Pty Ltd., Perth, Australia) . http://www.minemax.com/Google Scholar
  • Munirathinam M., Yingling J. C. A review of computer-based truck dispatching strategies for surface mining operations. Internat. J. Surface Mining Reclamation Environ. (1994) 8(1):1–15CrossrefGoogle Scholar
  • Mutagwaba W., Hudson J. Use of object-oriented simulation model to assess operating and equipment options for underground mine transport system. Mining Tech. IMM Trans. Sect. A (1993) 102:89–94Google Scholar
  • Najor J., Hagan P., Cardu M., Ciccu R., Lovera E., Michelotti E. Capacity constrained production scheduling. Proc. 15th Internat. Sympos. Mine Planning Equipment Selection (MPES) (2006) (FIORDO S.r.l., Torino, Italy) 1173–1178Google Scholar
  • Naoum S., Haidar A. A hybrid knowledge base system and genetic algorithms for equipment selection. Engrg. Construction Architectural Management (2000) 7(1):3–14CrossrefGoogle Scholar
  • Newman A., Kuchta M. Using aggregation to optimize long-term production planning at an underground mine. Eur. J. Oper. Res. (2007) 176(2):1205–1218CrossrefGoogle Scholar
  • Newman A., Yano C., Rubio E. Mining above and below ground: Timing the transition. (2009) . Working paper, Colorado School of Mines, GoldenGoogle Scholar
  • Onur A., Dowd P. Open-pit optimization part 2: Production scheduling and inclusion of roadways. Mining Tech.: IMM Trans. Sect. A (1993) 102:105–113Google Scholar
  • Oraee K., Asi B., Hardygora M., Paszkowska G., Sikora M. Fuzzy model for truck allocation in surface mines. Proc. 13th Internat. Sympos. Mine Planning Equipment Selection (MPES) (2004) Wroclaw, Poland:585–591Google Scholar
  • Osanloo M., Gholamnejad J., Karimi B. Long-term open pit mine production planning: A review of models and algorithms. Internat. J. Mining Reclamation Environ. (2008) 22(1):3–35CrossrefGoogle Scholar
  • Pendharkar P. A fuzzy linear programming model for production planning in coal mines. Comput. Oper. Res. (1997) 24(12):1141–1149CrossrefGoogle Scholar
  • Pendharkar P. C., Rodger J. A. Nonlinear programming and genetic search application for production scheduling in coal mines. Ann. Oper. Res. (2000) 95(1–4):251–267CrossrefGoogle Scholar
  • Qinglin C., Stillborg B., Li C., Hennies W., Ayres da Silva L., Chaves A. Optimization of underground mining methods using grey theory and neural networks. 5th Internat. Sympos. Mine Planning Equipment Selection (MPES) (1996) Sao Paulo, Brazil:393–398Google Scholar
  • Rahal D., Smith M., Van Hout G., Von Johannides A., Camisani-Calzolari F. The use of mixed integer linear programming for long-term scheduling in block caving mines. Proc. 31st Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos. (2003) (SAIMM, Cape Town, South Africa) 123–131Google Scholar
  • Ramazan S. The new fundamental tree algorithm for production scheduling of open pit mines. Eur. J. Oper. Res. (2007) 177(2):1153–1166CrossrefGoogle Scholar
  • Ramazan S., Dimitrakopoulos R. Traditional and new MIP models for production scheduling with in-situ grade variability. Internat. J. Surface Mining Reclamation Environ. (2004) 18(2):85–98CrossrefGoogle Scholar
  • Rubio E., Cardu M., Ciccu R., Lovera E., Michelotti E. Mill feed optimization for multiple processing facilities using integer linear programming. Proc. 15th Internat. Sympos. Mine Planning Equipment Selection (MPES) (2006) (FIORDO S.r.l., Torino, Italy) 1206–1212Google Scholar
  • Rubio E., Diering E., Karzulovic A., Alfaro M. Block cave production planning using operation research tools. Proc. MassMin 2004 (2004) (Instituto de Ingenieros de Chile, Santiago, Chile) 141–149Google Scholar
  • Samanta B., Bhattacherjee A., Ganguli R., Ganguli R., Dessureault S., Kecojevic V., Dwyer J. A genetic algorithms approach for grade control planning in a bauxite deposit. Proc. 32nd Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos. (2005) (SME, Littleton, CO) 337–342CrossrefGoogle Scholar
  • Sarin S. C., West-Hansen J. The long-term mine production scheduling problem. IIE Trans. (2005) 37(2):109–121CrossrefGoogle Scholar
  • Sevim H. Evaluation of underground coarse-coal slurry transportation systems by a simulation model. AIME Trans.: Part A—Oper. Res. (1987) 280:1817–1822Google Scholar
  • Sevim H., Lei D. The problem of production planning in open pit mines. Infor. Systems Oper. Res. (INFOR) J. (1998) 36(1–2):1–12CrossrefGoogle Scholar
  • Simsir F., Ozfirat M. K. Determination of the most effective longwall equipment combination in longwall top coal caving (LTCC) method by simulation modeling. Internat. J. Rock Mech. Mining Sci. (2008) 45(6):1015–1023CrossrefGoogle Scholar
  • Smith M., Sheppard I., Karunatillake G., Camisani-Calzolari F. Using MIP for strategic life-of-mine planning of the lead/zinc stream at Mount Isa Mines. Proc. 31st Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos. (2003) (SAIMM, Cape Town, South Africa) 465–474Google Scholar
  • Soumis F., Ethier J., Elbrond J. Truck dispatching in an open pit mine. Internat. J. Surface Mining Reclamation Environ. (1989) 3(2):115–119CrossrefGoogle Scholar
  • Sundar D. K., Acharya D. Blast schedule planning and shiftwise production scheduling of an opencast iron ore mine. Comput. Indust. Engrg. (1995) 28(4):927–935CrossrefGoogle Scholar
  • Ta C., Kresta J., Forbes J., Marquez H. A stochastic optimization approach to mine truck allocation. Internat. J. Surface Mining Reclamation Environ. (2005) 19(3):162–175CrossrefGoogle Scholar
  • Tan S., Ramani R. Optimization models for scheduling ore and waste production in open pit mines. Proc. 23rd Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos. (1992) (SME, Littleton, CO) 781–791Google Scholar
  • Topuz E., Breeds C., Karmis M., Haycocks C. Comparison of two underground haulage systems. Proc. 17th Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos. (1982) (SME, Littleton, CO) 614–619Google Scholar
  • Topuz E., Duan C. A survey of operations research applications in the mining industry. CIM Bull. (1989) 82(925):48–50Google Scholar
  • Trout L. Underground mine production scheduling using mixed integer programming. Proc. 25th Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos. (1995) (AusIMM)395–400Google Scholar
  • Underwood R., Tolwinski B. A mathematical programming viewpoint for solving the ultimate pit problem. Eur. J. Oper. Res. (1998) 107(1):96–107CrossrefGoogle Scholar
  • Vagenas N. Dispatch control of a fleet of remote-controlled/automatic load-haul-dump vehicles in underground mines. Internat. J. Prod. Res. (1991) 29(11):2347–2363CrossrefGoogle Scholar
  • Wang Q., Sun H., Xie H., Wang Y., Jiang Y. A theorem on open-pit planning optimization and its application. Proc. 29th Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos. (2001) (CUMT, Beijing) 295–298Google Scholar
  • Weintraub A., Barros L., Magendzo A., Ibarra F., Ortiz C., Rand G. A truck dispatching system for a large open pit mine. Proc. 11th Internat. Conf. Oper. Res. (1987) (North Holland, Amsterdam) 650–662Google Scholar
  • Weintraub A., Pereira M., Schultz X. A priori and a posteriori aggregation procedures to reduce model size in MIP mine planning models. Electronic Notes Discrete Math. (2008) 30:297–302CrossrefGoogle Scholar
  • White J., Olson J. On improving truck/shovel productivity in open pit mines. Proc. 23rd Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos. (1992) (SME, Littleton, CO) 739–746Google Scholar
  • Whittle Whittle Consulting global optimization software. (2009) (Melbourne, Australia). http://www.whittleconsulting.com.au/Google Scholar
  • Winkler B. System for quality oriented mine production planning with MOLP. Proc. 27th Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos. (1998) (Royal School of Mines, London) 53–59Google Scholar
  • Wright E., Weiss A. Dynamic programming in open pit mining sequence planning: A case study. Proc. 21st Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos. (1989) (SME, Littleton, CO) 415–422Google Scholar
  • Yun Q., Liu J., Chen Y., Huang G. Optimization of planning and design in underground mines. Proc. 22nd Internat. Appl. Comput. Oper. Res. Mineral Indust. (APCOM) Sympos. (1990) (Technische Universität Berlin, Berlin) 255Google Scholar
  • Zhang M., Cardu M., Ciccu R., Lovera E., Michelotti E. Combining genetic algorithms and topological sort to optimize open-pit mine plans. Proc. 15th Internat. Sympos. Mine Planning Equipment Selection (MPES) (2006) (FIORDO S.r.l., Torino, Italy) 1234–1239Google Scholar
Previous
Back to Top
Next
INFORMS site uses cookies to store information on your computer. Some are essential to make our site work; Others help us improve the user experience. By using this site, you consent to the placement of these cookies. Please read our Privacy Statement to learn more.
Agree