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A Reinforcement Learning Approach to Dynamic Scheduling in a Product-Mix Flexibility Environment

Yeou-Ren Shiue, Ken-Chuan Lee, Chao‐Ton Su

2020IEEE Access25 citationsDOIOpen Access PDF

Abstract

Machine bottlenecks, resulting from shifting and unbalanced machine loads caused by resource capacity limitations, impair product-mix flexibility production systems. Thus, the knowledge base (KB) of a dynamic scheduling control system should be dynamic and include a knowledge revision mechanism for monitoring crucial changes that occur in the production system. In this paper, reinforcement learning (RL)-based dynamic scheduling and a selection mechanism for multiple dynamic scheduling rules (MDSRs) are proposed to support the operating characteristics of a flexible manufacturing system (FMS) and semiconductor wafer fabrication (FAB). The proposed RL-based dynamic scheduling MDSR selection mechanism consisted of initial MDSR KB generation and revision phases. According to various performance criteria, the presented approach yields a system performance that is superior to those of the fixed-decision scheduling approach, the machine learning classification approach, and the classical MDSR selection mechanism.

Topics & Concepts

Reinforcement learningComputer scienceFlexibility (engineering)Scheduling (production processes)ReinforcementArtificial intelligenceMathematical optimizationEngineeringMathematicsStatisticsStructural engineeringScheduling and Optimization AlgorithmsSupply Chain and Inventory ManagementProduct Development and Customization
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