Digital Twin and Reinforcement Learning-Based Resilient Production Control for Micro Smart Factory

To achieve efficient personalized production at an affordable cost, a modular manufacturing system (MMS) can be utilized. MMS enables restructuring of its configuration to accommodate product changes and is thus an efficient solution to reduce the costs involved in personalized production. A micro smart factory (MSF) is an MMS with heterogeneous production processes to enable personalized production. Similar to MMS, MSF also enables the restructuring of production configuration; additionally, it comprises cyber-physical production systems (CPPSs) that help achieve resilience. However, MSFs need to overcome performance hurdles with respect to production control. Therefore, this paper proposes a digital twin (DT) and reinforcement learning (RL)-based production control method. This method replaces the existing dispatching rule in the type and instance phases of the MSF. In this method, the RL policy network is learned and evaluated by coordination between DT and RL. The DT provides virtual event logs that include states, actions, and rewards to support learning. These virtual event logs are returned based on vertical integration with the MSF. As a result, the proposed method provides a resilient solution to the CPPS architectural framework and achieves appropriate actions to the dynamic situation of MSF. Additionally, applying DT with RL helps decide what-next/where-next in the production cycle. Moreover, the proposed concept can be extended to various manufacturing domains because the priority rule concept is frequently applied.

[1]  Luis Ribeiro Cyber-physical production systems' design challenges , 2017, 2017 IEEE 26th International Symposium on Industrial Electronics (ISIE).

[2]  Der-Jiunn Deng,et al.  Smart Manufacturing Scheduling With Edge Computing Using Multiclass Deep Q Network , 2019, IEEE Transactions on Industrial Informatics.

[3]  Ashok Kumar,et al.  From mass customization to mass personalization: a strategic transformation , 2007 .

[4]  Xuehong Du,et al.  Understanding customer satisfaction in product customization , 2006 .

[5]  Jay Lee,et al.  Industrial Artificial Intelligence for industry 4.0-based manufacturing systems , 2018, Manufacturing Letters.

[6]  Xifan Yao,et al.  Emerging manufacturing paradigm shifts for the incoming industrial revolution , 2016 .

[7]  Abhijit Gosavi,et al.  Reinforcement Learning: A Tutorial Survey and Recent Advances , 2009, INFORMS J. Comput..

[8]  Mats Björkman,et al.  Transitioning From Standard Automation Solutions to Cyber-Physical Production Systems: An Assessment of Critical Conceptual and Technical Challenges , 2018, IEEE Systems Journal.

[9]  Sang Do Noh,et al.  Design and implementation of a digital twin application for a connected micro smart factory , 2019, Int. J. Comput. Integr. Manuf..

[10]  J. Y. Lee,et al.  The FaaS system using additive manufacturing for personalized production , 2018, Rapid Prototyping Journal.

[11]  Sang Do Noh,et al.  VREDI: virtual representation for a digital twin application in a work-center-level asset administration shell , 2020, J. Intell. Manuf..

[12]  Vladimír Vavrík,et al.  A Route Planner Using a Delegate Multi-Agent System for a Modular Manufacturing Line: Proof of Concept , 2019, Applied Sciences.

[13]  Fei Tao,et al.  Digital Twin and Big Data Towards Smart Manufacturing and Industry 4.0: 360 Degree Comparison , 2018, IEEE Access.

[14]  Sang Do Noh,et al.  Digital twin application with horizontal coordination for reinforcement-learning-based production control in a re-entrant job shop , 2021, Int. J. Prod. Res..

[15]  Monica Bellgran,et al.  Smart Factories: South Korean and Swedish examples on manufacturing settings , 2018 .

[16]  Kyu Tae Park,et al.  The architectural framework of a cyber physical logistics system for digital-twin-based supply chain control , 2020, Int. J. Prod. Res..

[17]  Jay Lee,et al.  A Cyber-Physical Systems architecture for Industry 4.0-based manufacturing systems , 2015 .

[18]  Sang Do Noh,et al.  Operation Procedures of a Work-Center-Level Digital Twin for Sustainable and Smart Manufacturing , 2020, International Journal of Precision Engineering and Manufacturing-Green Technology.

[19]  Alexandre Dolgui,et al.  Does the ripple effect influence the bullwhip effect? An integrated analysis of structural and operational dynamics in the supply chain† , 2019, Int. J. Prod. Res..

[20]  Martin A. Riedmiller,et al.  ADAPTIVE REACTIVE JOB-SHOP SCHEDULING WITH REINFORCEMENT LEARNING AGENTS , 2008 .

[21]  Eun Suk Suh,et al.  Level of modularity and different levels of system granularity , 2011 .

[22]  Warren P. Seering,et al.  THE INFLUENCE OF ARCHITECTURE IN ENGINEERING SYSTEMS , 2004 .

[23]  Alexandre Dolgui,et al.  The impact of digital technology and Industry 4.0 on the ripple effect and supply chain risk analytics , 2018, Int. J. Prod. Res..

[24]  Zhiwu Li,et al.  Automatic Supervisory Controller for Deadlock Control in Reconfigurable Manufacturing Systems with Dynamic Changes , 2020 .

[25]  Qiang Liu,et al.  Digital twin-driven rapid individualised designing of automated flow-shop manufacturing system , 2019, Int. J. Prod. Res..

[26]  He Zhang,et al.  Digital Twin in Industry: State-of-the-Art , 2019, IEEE Transactions on Industrial Informatics.

[27]  Felix T.S. Chan,et al.  Defining a Digital Twin-based Cyber-Physical Production System for autonomous manufacturing in smart shop floors , 2019, Int. J. Prod. Res..

[28]  Jaeseok Huh,et al.  A Reinforcement Learning Approach to Robust Scheduling of Semiconductor Manufacturing Facilities , 2020, IEEE Transactions on Automation Science and Engineering.

[29]  Jingda Wu,et al.  Battery Thermal- and Health-Constrained Energy Management for Hybrid Electric Bus Based on Soft Actor-Critic DRL Algorithm , 2021, IEEE Transactions on Industrial Informatics.

[30]  Lihui Wang,et al.  Smart manufacturing process and system automation – A critical review of the standards and envisioned scenarios , 2020 .

[31]  Dimitris Mourtzis,et al.  A cloud-based cyber-physical system for adaptive shop-floor scheduling and condition-based maintenance , 2018 .

[32]  Jay Lee,et al.  Industrial Big Data Analytics and Cyber-physical Systems for Future Maintenance & Service Innovation , 2015 .

[33]  Oliver Niggemann,et al.  Automatic Parameter Estimation for Reusable Software Components of Modular and Reconfigurable Cyber-Physical Production Systems in the Domain of Discrete Manufacturing , 2018, IEEE Transactions on Industrial Informatics.

[34]  Fei Tao,et al.  Cyber-physical integration for moving digital factories forward towards smart manufacturing: a survey , 2018 .

[35]  Sang Do Noh,et al.  Cyber Physical Energy System for Saving Energy of the Dyeing Process with Industrial Internet of Things and Manufacturing Big Data , 2019, International Journal of Precision Engineering and Manufacturing-Green Technology.

[36]  Soundar R. T. Kumara,et al.  Cyber-physical systems in manufacturing , 2016 .

[37]  Dimitris Mourtzis,et al.  Simulation in the design and operation of manufacturing systems: state of the art and new trends , 2019, Int. J. Prod. Res..

[38]  Jingda Wu,et al.  Battery-Involved Energy Management for Hybrid Electric Bus Based on Expert-Assistance Deep Deterministic Policy Gradient Algorithm , 2020, IEEE Transactions on Vehicular Technology.

[39]  Sang Do Noh,et al.  Digital twin-based cyber physical production system architectural framework for personalized production , 2019, The International Journal of Advanced Manufacturing Technology.

[40]  Sara Tucci Piergiovanni,et al.  Modeling business motivation and underlying processes for RAMI 4.0-aligned cyber-physical production systems , 2017, 2017 22nd IEEE International Conference on Emerging Technologies and Factory Automation (ETFA).

[41]  Lei Ren,et al.  Customized production based on distributed 3D printing services in cloud manufacturing , 2016 .

[42]  Tom Schaul,et al.  Dueling Network Architectures for Deep Reinforcement Learning , 2015, ICML.

[43]  Shane Legg,et al.  Massively Parallel Methods for Deep Reinforcement Learning , 2015, ArXiv.