Litcius/Paper detail

Decomposition-based real-time control of multi-stage transfer lines with residence time constraints

Feifan Wang, Feng Ju

2020IISE Transactions12 citationsDOI

Abstract

It is commonly observed in the food industry, battery production, automotive paint shop, and semiconductor manufacturing that an intermediate product’s residence time in the buffer within a production line is controlled by a time window to guarantee product quality. There is typically a minimum time limit reflected by a part’s travel time or process requirement. Meanwhile, these intermediate parts are prevented from staying in the buffer for too long by an upper time limit, exceeding which a part will be scrapped or need additional treatment. To increase production throughput and reduce scrap, one needs to control machines’ working mode according to real-time system information in the stochastic production environment, which is a difficult problem to solve, due to the system’s complexity. In this article, we propose a novel decomposition-based control approach by decomposing a production system into small-scale subsystems based on domain knowledge and their structural relationship. An iterative aggregation procedure is then used to generate a production control policy with convergence guarantee. Numerical studies suggest that the decomposition-based control approach outperforms general-purpose reinforcement learning method by delivering significant system performance improvement and substantial reduction on computation overhead.

Topics & Concepts

Computer scienceProduction lineThroughputControl limitsProduction controlScrapDecompositionProduction (economics)Limit (mathematics)Automotive industryIndustrial engineeringMathematical optimizationProcess (computing)EngineeringControl chartMathematicsMechanical engineeringMacroeconomicsAerospace engineeringMathematical analysisBiologyEcologyTelecommunicationsEconomicsWirelessOperating systemScheduling and Optimization AlgorithmsAssembly Line Balancing OptimizationElevator Systems and Control