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A Stochastic Mixed Integer Programming Framework for Underground Mining Production Scheduling Optimization Considering Grade Uncertainty

Shuwei Huang, Guoqing Li, Eugene Ben-Awuah, Bright Oppong Afum, Nailian Hu

2020IEEE Access28 citationsDOIOpen Access PDF

Abstract

Conventional mine planning approaches use an estimated orebody model as input to generate optimal production schedules. The smoothing effect of some geostatistical estimation methods cause most of the mine plans and production forecasts to be unrealistic and incomplete. With the development of simulation methods, the risks from grade uncertainty in ore reserves can be measured and managed through a set of equally probable orebody realizations. In order to incorporate grade uncertainty into the strategic mine plan, a stochastic mixed integer programming (SMIP) formulation is presented to optimize an underground cut-and-fill mining production schedule. The objective function of the SMIP model is to maximize the net present value (NPV) of the mining project and minimize the risk of deviation from the production targets. To demonstrate the applicability of the SMIP model, a case study on a cut-and-fill underground gold mining operation is implemented.

Topics & Concepts

Integer programmingProduction (economics)Production scheduleComputer scienceScheduleSmoothingScheduling (production processes)Stochastic programmingOpen-pit miningProduction planningMathematical optimizationNet present valueStandard deviationLinear programmingOperations researchMining engineeringAlgorithmEngineeringMathematicsStatisticsMacroeconomicsComputer visionEconomicsOperating systemMining Techniques and EconomicsBelt Conveyor Systems EngineeringMineral Processing and Grinding
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