TY - GEN
T1 - Real-time Dynamic Reconfiguration for IEC 61499
AU - Prenzel, Laurin
AU - Hofmann, Simon
AU - Steinhorst, Sebastian
N1 - Publisher Copyright:
© 2022 IEEE.
PY - 2022
Y1 - 2022
N2 - Reconfiguration is an important feature for industrial automation systems to provide flexibility, adaptability, and resilience. Dynamic reconfiguration of real-time systems requires both functional and temporal correctness. A lengthy disruption of real-time behaviors caused by a reconfiguration can cause the system to fail. We describe the scheduling problem for a component-based real-time industrial control system on the basis of the IEC 61499 and extend this problem to handle disruptions introduced by a dynamic reconfiguration. We show that the disruption can be quantified by applying the Priority Ceiling Protocol (PCP) and calculating the blocking time. Further, we show that the order of operations within a reconfiguration sequence can be optimized using the blocking time as objective function. An evaluation on two example systems shows that our model allows the application of common schedulability tests for Rate Monotonic scheduling. In our examples, the optimization reduces the blocking time of a task during reconfiguration compared to a heuristic topological ordering by up to 85%. This makes previously infeasible reconfigurations feasible. The results imply that timing analysis of dynamic reconfiguration for component-based real-time systems is attainable, and further research is necessary to extend it for distributed systems.
AB - Reconfiguration is an important feature for industrial automation systems to provide flexibility, adaptability, and resilience. Dynamic reconfiguration of real-time systems requires both functional and temporal correctness. A lengthy disruption of real-time behaviors caused by a reconfiguration can cause the system to fail. We describe the scheduling problem for a component-based real-time industrial control system on the basis of the IEC 61499 and extend this problem to handle disruptions introduced by a dynamic reconfiguration. We show that the disruption can be quantified by applying the Priority Ceiling Protocol (PCP) and calculating the blocking time. Further, we show that the order of operations within a reconfiguration sequence can be optimized using the blocking time as objective function. An evaluation on two example systems shows that our model allows the application of common schedulability tests for Rate Monotonic scheduling. In our examples, the optimization reduces the blocking time of a task during reconfiguration compared to a heuristic topological ordering by up to 85%. This makes previously infeasible reconfigurations feasible. The results imply that timing analysis of dynamic reconfiguration for component-based real-time systems is attainable, and further research is necessary to extend it for distributed systems.
KW - Downtimeless System Evolution
KW - Dynamic Reconfiguration
KW - Dynamic Soft-ware Updating
KW - Timing Analysis
UR - http://www.scopus.com/inward/record.url?scp=85135621574&partnerID=8YFLogxK
U2 - 10.1109/ICPS51978.2022.9816872
DO - 10.1109/ICPS51978.2022.9816872
M3 - Conference contribution
AN - SCOPUS:85135621574
T3 - Proceedings - 2022 IEEE 5th International Conference on Industrial Cyber-Physical Systems, ICPS 2022
BT - Proceedings - 2022 IEEE 5th International Conference on Industrial Cyber-Physical Systems, ICPS 2022
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 5th IEEE International Conference on Industrial Cyber-Physical Systems, ICPS 2022
Y2 - 24 May 2022 through 26 May 2022
ER -