A Generative DRL Framework for Adaptive Quality Control in Industrial Cyber-Physical Production Systems

Pengshuo Wang; Wenjing Xiao; Miaojiang Chen; Yueqian Zhang; Qingnian Li; Jiarong Liang; Ahmed Farouk

doi:10.1109/TICPS.2026.3663105

A Generative DRL Framework for Adaptive Quality Control in Industrial Cyber-Physical Production Systems

Pengshuo Wang
, Wenjing Xiao
, Miaojiang Chen^*
, Yueqian Zhang
, Qingnian Li
, Jiarong Liang^*
, Ahmed Farouk

^*Corresponding author for this work

Guangxi University
Nanning University
Hurghada University

Research output: Contribution to journal › Article › peer-review

Abstract

The manufacturing sector faces escalating pressures to enhance production efficiency, product yield, and energy utilization, making Intelligent Quality Inspection (IQI) a cornerstone of product reliability. To address this need, we propose a data-driven decision-making framework for IQI, grounded in generative artificial intelligence and deep reinforcement learning. This study focuses on the component assembly process, a critical stage in manufacturing. We first develop a generative AI-driven daptive framework that constructs a high-fidelity assembly line. This environment realistically incorporates stochastic factors such as component defective rates, inspection mechanisms, and handling strategies for non-conforming products. To provide a rigorous foundation for algorithmic optimization, we formally model this dynamic ecosystem as a Markov Decision Process (MDP), defining its state space and probabilistic transition rules. We then introduce the integrated Rainbow Deep Q-Network (Rainbow DQN) algorithm to solve the resulting multi-step sequential decision-making problem. Our approach leverages the synergistic advantages of multiple DQN extensions to master dynamic quality control policies. Extensive experimental evaluations, including ablation studies and comparisons against benchmark algorithms such as traditional Monte Carlo methods, confirm the superiority of our proposed framework. The results demonstrate significant advantages in convergence speed, decision-making accuracy, and computational efficiency, underscoring its potential to advance the capabilities of intelligent quality inspection in modern industrial cyber-physical systems.

Original language	English
Pages (from-to)	119-128
Number of pages	10
Journal	IEEE Transactions on Industrial Cyber-Physical Systems
Volume	4
DOIs	https://doi.org/10.1109/TICPS.2026.3663105
Publication status	Published - 2026
Externally published	Yes

Keywords

Adaptive Quality Control
Assembly
Costs
Decision making
Deep reinforcement learning
Generative deep reinforcement learning
Heuristic algorithms
Industrial Cyber-Physical Systems
Inspection
Markov decision processes
Optimization
Production
Quality control

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10.1109/TICPS.2026.3663105

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title = "A Generative DRL Framework for Adaptive Quality Control in Industrial Cyber-Physical Production Systems",

abstract = "The manufacturing sector faces escalating pressures to enhance production efficiency, product yield, and energy utilization, making Intelligent Quality Inspection (IQI) a cornerstone of product reliability. To address this need, we propose a data-driven decision-making framework for IQI, grounded in generative artificial intelligence and deep reinforcement learning. This study focuses on the component assembly process, a critical stage in manufacturing. We first develop a generative AI-driven daptive framework that constructs a high-fidelity assembly line. This environment realistically incorporates stochastic factors such as component defective rates, inspection mechanisms, and handling strategies for non-conforming products. To provide a rigorous foundation for algorithmic optimization, we formally model this dynamic ecosystem as a Markov Decision Process (MDP), defining its state space and probabilistic transition rules. We then introduce the integrated Rainbow Deep Q-Network (Rainbow DQN) algorithm to solve the resulting multi-step sequential decision-making problem. Our approach leverages the synergistic advantages of multiple DQN extensions to master dynamic quality control policies. Extensive experimental evaluations, including ablation studies and comparisons against benchmark algorithms such as traditional Monte Carlo methods, confirm the superiority of our proposed framework. The results demonstrate significant advantages in convergence speed, decision-making accuracy, and computational efficiency, underscoring its potential to advance the capabilities of intelligent quality inspection in modern industrial cyber-physical systems.",

keywords = "Adaptive Quality Control, Assembly, Costs, Decision making, Deep reinforcement learning, Generative deep reinforcement learning, Heuristic algorithms, Industrial Cyber-Physical Systems, Inspection, Markov decision processes, Optimization, Production, Quality control",

author = "Pengshuo Wang and Wenjing Xiao and Miaojiang Chen and Yueqian Zhang and Qingnian Li and Jiarong Liang and Ahmed Farouk",

note = "Publisher Copyright: {\textcopyright} 2023 IEEE.",

year = "2026",

doi = "10.1109/TICPS.2026.3663105",

language = "English",

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journal = "IEEE Transactions on Industrial Cyber-Physical Systems",

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T1 - A Generative DRL Framework for Adaptive Quality Control in Industrial Cyber-Physical Production Systems

AU - Wang, Pengshuo

AU - Xiao, Wenjing

AU - Chen, Miaojiang

AU - Zhang, Yueqian

AU - Li, Qingnian

AU - Liang, Jiarong

AU - Farouk, Ahmed

PY - 2026

Y1 - 2026

N2 - The manufacturing sector faces escalating pressures to enhance production efficiency, product yield, and energy utilization, making Intelligent Quality Inspection (IQI) a cornerstone of product reliability. To address this need, we propose a data-driven decision-making framework for IQI, grounded in generative artificial intelligence and deep reinforcement learning. This study focuses on the component assembly process, a critical stage in manufacturing. We first develop a generative AI-driven daptive framework that constructs a high-fidelity assembly line. This environment realistically incorporates stochastic factors such as component defective rates, inspection mechanisms, and handling strategies for non-conforming products. To provide a rigorous foundation for algorithmic optimization, we formally model this dynamic ecosystem as a Markov Decision Process (MDP), defining its state space and probabilistic transition rules. We then introduce the integrated Rainbow Deep Q-Network (Rainbow DQN) algorithm to solve the resulting multi-step sequential decision-making problem. Our approach leverages the synergistic advantages of multiple DQN extensions to master dynamic quality control policies. Extensive experimental evaluations, including ablation studies and comparisons against benchmark algorithms such as traditional Monte Carlo methods, confirm the superiority of our proposed framework. The results demonstrate significant advantages in convergence speed, decision-making accuracy, and computational efficiency, underscoring its potential to advance the capabilities of intelligent quality inspection in modern industrial cyber-physical systems.

AB - The manufacturing sector faces escalating pressures to enhance production efficiency, product yield, and energy utilization, making Intelligent Quality Inspection (IQI) a cornerstone of product reliability. To address this need, we propose a data-driven decision-making framework for IQI, grounded in generative artificial intelligence and deep reinforcement learning. This study focuses on the component assembly process, a critical stage in manufacturing. We first develop a generative AI-driven daptive framework that constructs a high-fidelity assembly line. This environment realistically incorporates stochastic factors such as component defective rates, inspection mechanisms, and handling strategies for non-conforming products. To provide a rigorous foundation for algorithmic optimization, we formally model this dynamic ecosystem as a Markov Decision Process (MDP), defining its state space and probabilistic transition rules. We then introduce the integrated Rainbow Deep Q-Network (Rainbow DQN) algorithm to solve the resulting multi-step sequential decision-making problem. Our approach leverages the synergistic advantages of multiple DQN extensions to master dynamic quality control policies. Extensive experimental evaluations, including ablation studies and comparisons against benchmark algorithms such as traditional Monte Carlo methods, confirm the superiority of our proposed framework. The results demonstrate significant advantages in convergence speed, decision-making accuracy, and computational efficiency, underscoring its potential to advance the capabilities of intelligent quality inspection in modern industrial cyber-physical systems.

KW - Adaptive Quality Control

KW - Assembly

KW - Costs

KW - Decision making

KW - Deep reinforcement learning

KW - Generative deep reinforcement learning

KW - Heuristic algorithms

KW - Industrial Cyber-Physical Systems

KW - Inspection

KW - Markov decision processes

KW - Optimization

KW - Production

KW - Quality control

UR - https://www.scopus.com/pages/publications/105036905180

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M3 - Article

AN - SCOPUS:105036905180

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EP - 128

JO - IEEE Transactions on Industrial Cyber-Physical Systems

JF - IEEE Transactions on Industrial Cyber-Physical Systems

ER -

A Generative DRL Framework for Adaptive Quality Control in Industrial Cyber-Physical Production Systems

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Keywords

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