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Main Authors: Waseem, Muhammad, Chang, Qing
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2504.20053
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author Waseem, Muhammad
Chang, Qing
author_facet Waseem, Muhammad
Chang, Qing
contents The present volatile global market is marked by a rising need for extensively tailored products. Flourishing in such an environment necessitates fostering a more intimate connection between market requirements and the manufacturing system, with a primary emphasis on the customer. Multiproduct flexible manufacturing systems (FMS) appear to be one of the most suitable manufacturing systems for mass-customization, given their capacity to readily adapt to variations in product specifications and functionalities to meet evolving market demands. Mobile robots play a pivotal role in managing multiproduct FMS. However, scheduling these robots poses a challenging problem due to system internal uncertainties and fluctuations in external demand. This paper proposes a solution to the robots' scheduling problem in a multiproduct FMS with stochastic machine failures and uncertain market demand for different product types. The proposed approach abstracts system properties for FMS and leverages these properties to improve the multiagent deep deterministic policy gradient (MADDPG) algorithm. This modification involves integrating parallel layers into the critic network, focusing specifically on crucial information such as varying customer demands. To validate the effectiveness of the proposed method, a comprehensive comparative analysis is conducted, comparing it with the simple-MADDPG, DDPG, and DQN algorithms. The results of the analysis demonstrate an average improvement of 9% in training time and 19% in market demand satisfaction. Moreover, to ensure scalability, transfer learning is employed, showcasing the applicability of the proposed method in large-scale complex environments.
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spellingShingle Enhancing Flexibility in Smart Manufacturing: System Property Enabled Multiagent Approach for Mobile Robot Scheduling in Multiproduct Flexible Manufacturing Systems
Waseem, Muhammad
Chang, Qing
Optimization and Control
The present volatile global market is marked by a rising need for extensively tailored products. Flourishing in such an environment necessitates fostering a more intimate connection between market requirements and the manufacturing system, with a primary emphasis on the customer. Multiproduct flexible manufacturing systems (FMS) appear to be one of the most suitable manufacturing systems for mass-customization, given their capacity to readily adapt to variations in product specifications and functionalities to meet evolving market demands. Mobile robots play a pivotal role in managing multiproduct FMS. However, scheduling these robots poses a challenging problem due to system internal uncertainties and fluctuations in external demand. This paper proposes a solution to the robots' scheduling problem in a multiproduct FMS with stochastic machine failures and uncertain market demand for different product types. The proposed approach abstracts system properties for FMS and leverages these properties to improve the multiagent deep deterministic policy gradient (MADDPG) algorithm. This modification involves integrating parallel layers into the critic network, focusing specifically on crucial information such as varying customer demands. To validate the effectiveness of the proposed method, a comprehensive comparative analysis is conducted, comparing it with the simple-MADDPG, DDPG, and DQN algorithms. The results of the analysis demonstrate an average improvement of 9% in training time and 19% in market demand satisfaction. Moreover, to ensure scalability, transfer learning is employed, showcasing the applicability of the proposed method in large-scale complex environments.
title Enhancing Flexibility in Smart Manufacturing: System Property Enabled Multiagent Approach for Mobile Robot Scheduling in Multiproduct Flexible Manufacturing Systems
topic Optimization and Control
url https://arxiv.org/abs/2504.20053