A Feasible Schedule for Parallel Assembly Tasks in Flexible Manufacturing Systems

Baccelli, F., Cohen, G., Olsder, G.J. and Quadrat, J.-P. (1992). Synchronization and Linearity: An Algebra for Discrete Event Systems, John Wiley& Sons, Hoboken. Search in Google Scholar

Baruwa, O.T., Piera, M.A. and Guasch, A. (2015). Deadlock-free scheduling method for flexible manufacturing systems based on timed colored Petri nets and anytime heuristic search, IEEE Transactions on Systems, Man, and Cybernetics: Systems 45(5): 1–12.10.1109/TSMC.2014.2376471 Search in Google Scholar

Butkovic, P. (2010). Max-Linear Systems: Theory and Algorithms, Springer, London.10.1007/978-1-84996-299-5 Search in Google Scholar

Dizdar, E.N. and Koçar, O. (2020). Fuzzy logic-based decision-making system design for safe forklift truck speed: Cast cobblestone production application, Soft Computing 24(19): 1–14.10.1007/s00500-020-04843-6 Search in Google Scholar

Ebrahimi, A., Sajadi, S., Roshanzamir, P. and Azizi, M. (2015). Determining the optimal performance of flexible manufacturing systems using network analysis and simulation process, International Journal of Management, Economics and and Social Sciences 4(1): 12–17. Search in Google Scholar

Groover, M. (2014). Automation, Production Systems, and Computer-Integrated Manufacturing, 3rd Edition, Pearson, London. Search in Google Scholar

Kopetz, H. (2011). Real-Time Systems: Design Principles for Distributed Embedded Applications, Springer, Boston.10.1007/978-1-4419-8237-7_11 Search in Google Scholar

Madakam, S., Ramaswamy R. and Tripathi, S. (2015). Internet of things (IoT): A literature review, Journl of Computing and Communications 3(05): 164.10.4236/jcc.2015.35021 Search in Google Scholar

Majdzik, P. (2020). Feasible schedule under faults in the assembly system, 2020 16th International Conference on Control, Automation, Robotics and Vision (ICARCV), Shenzhen, China, pp. 1049–1054. Search in Google Scholar

Majdzik, P., Akielaszek-Witczak, A., Seybold, L., Stetter, R. and Mrugalska, B. (2016). A fault-tolerant approach to the control of a battery assembly system, Control Engineering Practice 55: 139–148.10.1016/j.conengprac.2016.07.001 Search in Google Scholar

Majdzik, P., Witczak, M., Lipiec, B. and Banaszak, Z. (2021). Integrated fault-tolerant control of assembly and automated guided vehicle-based transportation layers, International Journal of Computer Integrated Manufacturing: 1–18, DOI: 10.1080/0951192X.2021.1872103.10.1080/0951192X.2021.1872103 Search in Google Scholar

Mircetic, D., Ralevic, N., Nikolicic, S., Maslaric, M. and Stojanovic, D. (2016). Expert system models for forecasting forklifts engagement in a warehouse loading operation: A case study, PROMET— Traffic&Transportation 28(4): 393–401.10.7307/ptt.v28i4.1900 Search in Google Scholar

Nivolianitou, Z. and Konstantinidou, M. (2018). A fuzzy modeling application for human reliability analysis in the process industry, in H. Pham (Ed.), Human Factors and Reliability Engineering for Safety and Security in Critical Infrastructures, Springer, London, pp. 109–154.10.1007/978-3-319-62319-1_5 Search in Google Scholar

RAFI GmbH & Co. KG (2021). KIS.ME User Manual, RAFI GmbH & Co. KG, Berg, https://kisme.rafi.de/documents/KISME-UserManual.pdf. Search in Google Scholar

Rousset, A., Herrmann, B., Lang, C. and Philippe, L. (2016). A survey on parallel and distributed multi-agent systems for high performance computing simulations, Computer Science Review 22: 27–46.10.1016/j.cosrev.2016.08.001 Search in Google Scholar

Rutkowski, T., Łapa, K. and Nielek, R. (2019). On explainable fuzzy recommenders and their performance evaluation, International Journal of Applied Mathematics and Computer Science 29(3): 595–610, DOI: 10.2478/amcs-2019-0044.10.2478/amcs-2019-0044 Search in Google Scholar

Salazar, J.C., Sanjuan, A., Nejjari, F. and Sarrate, R. (2020). Health-aware and fault-tolerant control of an octorotor UAV system based on actuator reliability, International Journal of Applied Mathematics and Computer Science 30(1): 47–59, DOI: 10.34768/amcs-2020-0004. Search in Google Scholar

Segura, M.A., Hennequin, S. and Finel, B. (2016). Human factor modelled by fuzzy logic in preventive maintenance actions, International Journal of Operational Research 27(1–2): 316–340.10.1504/IJOR.2016.078468 Search in Google Scholar

Seybold, L., Witczak, M., Majdzik, P. and Stetter, R. (2015). Towards robust predictive fault-tolerant control for a battery assembly system, International Journal of Applied Mathematics and Computer Science 25(4): 849–862, DOI: 10.1515/amcs-2015-0061.10.1515/amcs-2015-0061 Search in Google Scholar

Tanaka, K. and Sugeno, M. (1992). Stability analysis and design of fuzzy control systems, Fuzzy Sets and Systems 45(2): 135–156.10.1016/0165-0114(92)90113-I Search in Google Scholar

Van Den Boom, T. and De Schutter, B. (2006). Modelling and control of discrete event systems using switching max-plus-linear systems, Control Engineering Practice 14(10): 1199–1211.10.1016/j.conengprac.2006.02.006 Search in Google Scholar

Witczak, M. (2014). Fault Diagnosis and Fault-Tolerant Control Strategies for Non-Linear Systems, Springer, Heidelberg.10.1007/978-3-319-03014-2 Search in Google Scholar

Witczak, M., Majdzik, P., Stetter, R. and Lipiec, B. (2019). Multiple AGV fault-tolerant within an agile manufacturing warehouse, IFAC-PapersOnLine 52(13): 1914–1919.10.1016/j.ifacol.2019.11.482 Search in Google Scholar

Witczak, M., Majdzik, P., Stetter, R. and Lipiec, B. (2020). A fault-tolerant control strategy for multiple automated guided vehicles, Journal of Manufacturing Systems 55(4): 56–68.10.1016/j.jmsy.2020.02.009 Search in Google Scholar