TY - GEN
T1 - High fidelity real-time hybrid substructure testing using iterative learning control
AU - Insam, Christina
AU - Kist, Arian
AU - Rixen, Daniel J.
N1 - Publisher Copyright:
© 2020 VDE Verlag GMBH.
PY - 2020
Y1 - 2020
N2 - Testing of critical parts is a crucial step in ensuring a timely and cost-effective development of complex dynamical systems. Tests should be carried out with realistic boundary conditions and high fidelity such that the function of a component in the later application can be assured. Real-Time Hybrid Substructuring (RTHS) is a test method that enables testing of critical parts under realistic boundary conditions. Here, the critical part is mounted on a test bench and coupled in real-time to a co-simulation of the surrounding structure. The coupling involves a controlled actuator and, for a high fidelity of the RTHS test outcome, the tracking of this actuator needs to be ideal. If the actuator is not ideal and introduces its own dynamics, it makes the coupling inaccurate and at worst even unstable. In this contribution, we investigate the applicability of P-type Iterative Learning Control (PILC) to RTHS and whether it can improve the tracking performance of the actuator and thus the fidelity of the test for consecutive trials. We investigated a one-dimensional mass-spring-mass system using RTHS and PILC and performed RTHS tests. The tests were first conducted purely in simulations and then experimentally. We considered two distinct cases: (i) a system where the coupling is stable but inaccurate in the first iteration and (ii) a system that is unstable due to actuator dynamics in the first iteration. Results reveal that the PILC manages to improve tracking performance and fidelity of the RTHS test for the stable system (i), but it does not stabilize the unstable coupling (ii). This preliminary research implies that PILC can be a useful tool to improve the fidelity of RTHS tests. However, the robustness of the scheme needs to be improved in future work.
AB - Testing of critical parts is a crucial step in ensuring a timely and cost-effective development of complex dynamical systems. Tests should be carried out with realistic boundary conditions and high fidelity such that the function of a component in the later application can be assured. Real-Time Hybrid Substructuring (RTHS) is a test method that enables testing of critical parts under realistic boundary conditions. Here, the critical part is mounted on a test bench and coupled in real-time to a co-simulation of the surrounding structure. The coupling involves a controlled actuator and, for a high fidelity of the RTHS test outcome, the tracking of this actuator needs to be ideal. If the actuator is not ideal and introduces its own dynamics, it makes the coupling inaccurate and at worst even unstable. In this contribution, we investigate the applicability of P-type Iterative Learning Control (PILC) to RTHS and whether it can improve the tracking performance of the actuator and thus the fidelity of the test for consecutive trials. We investigated a one-dimensional mass-spring-mass system using RTHS and PILC and performed RTHS tests. The tests were first conducted purely in simulations and then experimentally. We considered two distinct cases: (i) a system where the coupling is stable but inaccurate in the first iteration and (ii) a system that is unstable due to actuator dynamics in the first iteration. Results reveal that the PILC manages to improve tracking performance and fidelity of the RTHS test for the stable system (i), but it does not stabilize the unstable coupling (ii). This preliminary research implies that PILC can be a useful tool to improve the fidelity of RTHS tests. However, the robustness of the scheme needs to be improved in future work.
UR - http://www.scopus.com/inward/record.url?scp=85101075908&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:85101075908
T3 - 52nd International Symposium on Robotics, ISR 2020
SP - 85
EP - 91
BT - 52nd International Symposium on Robotics, ISR 2020
PB - VDE VERLAG GMBH
T2 - 52nd International Symposium on Robotics, ISR 2020
Y2 - 9 December 2020 through 10 December 2020
ER -