Comparison of feedforward control schemes for real-time hybrid substructuring (rths)

Christina Insam; Mert Göldeli; Tobias Klotz; Daniel J. Rixen

doi:10.1007/978-3-030-47630-4_1

Comparison of feedforward control schemes for real-time hybrid substructuring (rths)

Christina Insam, Mert Göldeli, Tobias Klotz, Daniel J. Rixen

Chair of Applied Mechanics

Technical University of Munich

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

6 Scopus citations

Abstract

In order to meet the high demands in testing, actuators must be able to follow their desired displacement with high precision. Feedforward control enables high tracking performance of actuators. In combination with feedback controllers, an actuator can follow a prescribed trajectory quickly, stably and robustly under varying conditions. In Real-Time Hybrid Substructuring (RTHS), a method where parts can be tested under realistic boundary conditions, high tracking performance of the actuator is vital. It not only increases fidelity of the RTHS test outcome—meaning that the test replicates the environment and boundary conditions of the test specimen well—but it also prevents the RTHS loop from becoming unstable. Hence, research is carried out in the field of control schemes being applied to RTHS systems. In this work, the existing cascaded feedback control of the position controlled Stewart Platform is expanded by three different feedforward control schemes: model-based dynamic feedforward, modeling-free iterative learning control and velocity feedforward. The tracking performances are compared and discussed using a commanded sine trajectory. Results reveal that modeling-free iterative learning control and velocity feedforward outperform model-based dynamic feedforward and follow the desired trajectory with high amplitude and phase accuracy. Velocity feedforward is simple and requires almost no implementation effort. Thus it is recommended for applications with stiff actuators. In contrast, modeling-free iterative learning control is recommended for tasks where the actuator is not stiff compared to the test specimen. As all these feedforward control schemes improve the tracking performance compared to feedback control, the fidelity of the RTHS test will improve using them.

Original language	English
Title of host publication	Dynamic Substructures, Volume 4 - Proceedings of the 38th IMAC, A Conference and Exposition on Structural Dynamics, 2020
Editors	Andreas Linderholt, Matt Allen, Walter D’Ambrogio
Publisher	Springer
Pages	1-14
Number of pages	14
ISBN (Print)	9783030476298
DOIs	https://doi.org/10.1007/978-3-030-47630-4_1
State	Published - 2021
Event	38th IMAC, A Conference and Exposition on Structural Dynamics, 2020 - Houston, United States Duration: 10 Feb 2020 → 13 Feb 2020

Publication series

Name	Conference Proceedings of the Society for Experimental Mechanics Series
ISSN (Print)	2191-5644
ISSN (Electronic)	2191-5652

Conference

Conference	38th IMAC, A Conference and Exposition on Structural Dynamics, 2020
Country/Territory	United States
City	Houston
Period	10/02/20 → 13/02/20

Keywords

Feedforward control for RTHS
Model-based dynamic feedforward
Modeling-free iterative learning control
Parallel manipulators
Velocity feedforward

Access to Document

10.1007/978-3-030-47630-4_1

Cite this

Insam, C., Göldeli, M., Klotz, T., & Rixen, D. J. (2021). Comparison of feedforward control schemes for real-time hybrid substructuring (rths). In A. Linderholt, M. Allen, & W. D’Ambrogio (Eds.), Dynamic Substructures, Volume 4 - Proceedings of the 38th IMAC, A Conference and Exposition on Structural Dynamics, 2020 (pp. 1-14). (Conference Proceedings of the Society for Experimental Mechanics Series). Springer. https://doi.org/10.1007/978-3-030-47630-4_1

Insam, Christina ; Göldeli, Mert ; Klotz, Tobias et al. / Comparison of feedforward control schemes for real-time hybrid substructuring (rths). Dynamic Substructures, Volume 4 - Proceedings of the 38th IMAC, A Conference and Exposition on Structural Dynamics, 2020. editor / Andreas Linderholt ; Matt Allen ; Walter D’Ambrogio. Springer, 2021. pp. 1-14 (Conference Proceedings of the Society for Experimental Mechanics Series).

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abstract = "In order to meet the high demands in testing, actuators must be able to follow their desired displacement with high precision. Feedforward control enables high tracking performance of actuators. In combination with feedback controllers, an actuator can follow a prescribed trajectory quickly, stably and robustly under varying conditions. In Real-Time Hybrid Substructuring (RTHS), a method where parts can be tested under realistic boundary conditions, high tracking performance of the actuator is vital. It not only increases fidelity of the RTHS test outcome—meaning that the test replicates the environment and boundary conditions of the test specimen well—but it also prevents the RTHS loop from becoming unstable. Hence, research is carried out in the field of control schemes being applied to RTHS systems. In this work, the existing cascaded feedback control of the position controlled Stewart Platform is expanded by three different feedforward control schemes: model-based dynamic feedforward, modeling-free iterative learning control and velocity feedforward. The tracking performances are compared and discussed using a commanded sine trajectory. Results reveal that modeling-free iterative learning control and velocity feedforward outperform model-based dynamic feedforward and follow the desired trajectory with high amplitude and phase accuracy. Velocity feedforward is simple and requires almost no implementation effort. Thus it is recommended for applications with stiff actuators. In contrast, modeling-free iterative learning control is recommended for tasks where the actuator is not stiff compared to the test specimen. As all these feedforward control schemes improve the tracking performance compared to feedback control, the fidelity of the RTHS test will improve using them.",

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Insam, C, Göldeli, M, Klotz, T & Rixen, DJ 2021, Comparison of feedforward control schemes for real-time hybrid substructuring (rths). in A Linderholt, M Allen & W D’Ambrogio (eds), Dynamic Substructures, Volume 4 - Proceedings of the 38th IMAC, A Conference and Exposition on Structural Dynamics, 2020. Conference Proceedings of the Society for Experimental Mechanics Series, Springer, pp. 1-14, 38th IMAC, A Conference and Exposition on Structural Dynamics, 2020, Houston, United States, 10/02/20. https://doi.org/10.1007/978-3-030-47630-4_1

Comparison of feedforward control schemes for real-time hybrid substructuring (rths). / Insam, Christina; Göldeli, Mert; Klotz, Tobias et al.
Dynamic Substructures, Volume 4 - Proceedings of the 38th IMAC, A Conference and Exposition on Structural Dynamics, 2020. ed. / Andreas Linderholt; Matt Allen; Walter D’Ambrogio. Springer, 2021. p. 1-14 (Conference Proceedings of the Society for Experimental Mechanics Series).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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N2 - In order to meet the high demands in testing, actuators must be able to follow their desired displacement with high precision. Feedforward control enables high tracking performance of actuators. In combination with feedback controllers, an actuator can follow a prescribed trajectory quickly, stably and robustly under varying conditions. In Real-Time Hybrid Substructuring (RTHS), a method where parts can be tested under realistic boundary conditions, high tracking performance of the actuator is vital. It not only increases fidelity of the RTHS test outcome—meaning that the test replicates the environment and boundary conditions of the test specimen well—but it also prevents the RTHS loop from becoming unstable. Hence, research is carried out in the field of control schemes being applied to RTHS systems. In this work, the existing cascaded feedback control of the position controlled Stewart Platform is expanded by three different feedforward control schemes: model-based dynamic feedforward, modeling-free iterative learning control and velocity feedforward. The tracking performances are compared and discussed using a commanded sine trajectory. Results reveal that modeling-free iterative learning control and velocity feedforward outperform model-based dynamic feedforward and follow the desired trajectory with high amplitude and phase accuracy. Velocity feedforward is simple and requires almost no implementation effort. Thus it is recommended for applications with stiff actuators. In contrast, modeling-free iterative learning control is recommended for tasks where the actuator is not stiff compared to the test specimen. As all these feedforward control schemes improve the tracking performance compared to feedback control, the fidelity of the RTHS test will improve using them.

AB - In order to meet the high demands in testing, actuators must be able to follow their desired displacement with high precision. Feedforward control enables high tracking performance of actuators. In combination with feedback controllers, an actuator can follow a prescribed trajectory quickly, stably and robustly under varying conditions. In Real-Time Hybrid Substructuring (RTHS), a method where parts can be tested under realistic boundary conditions, high tracking performance of the actuator is vital. It not only increases fidelity of the RTHS test outcome—meaning that the test replicates the environment and boundary conditions of the test specimen well—but it also prevents the RTHS loop from becoming unstable. Hence, research is carried out in the field of control schemes being applied to RTHS systems. In this work, the existing cascaded feedback control of the position controlled Stewart Platform is expanded by three different feedforward control schemes: model-based dynamic feedforward, modeling-free iterative learning control and velocity feedforward. The tracking performances are compared and discussed using a commanded sine trajectory. Results reveal that modeling-free iterative learning control and velocity feedforward outperform model-based dynamic feedforward and follow the desired trajectory with high amplitude and phase accuracy. Velocity feedforward is simple and requires almost no implementation effort. Thus it is recommended for applications with stiff actuators. In contrast, modeling-free iterative learning control is recommended for tasks where the actuator is not stiff compared to the test specimen. As all these feedforward control schemes improve the tracking performance compared to feedback control, the fidelity of the RTHS test will improve using them.

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Insam C, Göldeli M, Klotz T, Rixen DJ. Comparison of feedforward control schemes for real-time hybrid substructuring (rths). In Linderholt A, Allen M, D’Ambrogio W, editors, Dynamic Substructures, Volume 4 - Proceedings of the 38th IMAC, A Conference and Exposition on Structural Dynamics, 2020. Springer. 2021. p. 1-14. (Conference Proceedings of the Society for Experimental Mechanics Series). doi: 10.1007/978-3-030-47630-4_1

Comparison of feedforward control schemes for real-time hybrid substructuring (rths)

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Keywords

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