A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Compensation of actuator delay and dynamics for real‐time hybrid structural simulation
10.1002/eqe.743.abs
Compensation of delay and dynamic response of servo‐hydraulic actuators is critical for stability and accuracy of hybrid experimental and numerical simulations of seismic response of structures. In this study, current procedures for compensation of actuator delay are examined and improved procedures are proposed to minimize experimental errors. The new procedures require little or no a priori information about the behavior of the test specimen or the input excitation. First, a simple approach is introduced for rapid online estimation of system delay and actuator command gain, thus capturing the variability of system response through a simulation. Second, an extrapolation procedure for delay compensation, based on the same kinematics equations used in numerical integration procedures is examined. Simulations using the proposed procedures indicate a reduction in high‐frequency noise in force measurements that can minimize the excitation of high‐frequency modes. To further verify the effectiveness of the compensation procedures, the artificial energy added to a hybrid simulation as a result of actuator tracking errors is measured and used for demonstrating the improved accuracy in the simulations. Copyright © 2007 John Wiley & Sons, Ltd.
Compensation of actuator delay and dynamics for real‐time hybrid structural simulation
10.1002/eqe.743.abs
Compensation of delay and dynamic response of servo‐hydraulic actuators is critical for stability and accuracy of hybrid experimental and numerical simulations of seismic response of structures. In this study, current procedures for compensation of actuator delay are examined and improved procedures are proposed to minimize experimental errors. The new procedures require little or no a priori information about the behavior of the test specimen or the input excitation. First, a simple approach is introduced for rapid online estimation of system delay and actuator command gain, thus capturing the variability of system response through a simulation. Second, an extrapolation procedure for delay compensation, based on the same kinematics equations used in numerical integration procedures is examined. Simulations using the proposed procedures indicate a reduction in high‐frequency noise in force measurements that can minimize the excitation of high‐frequency modes. To further verify the effectiveness of the compensation procedures, the artificial energy added to a hybrid simulation as a result of actuator tracking errors is measured and used for demonstrating the improved accuracy in the simulations. Copyright © 2007 John Wiley & Sons, Ltd.
Compensation of actuator delay and dynamics for real‐time hybrid structural simulation
Ahmadizadeh, M. (author) / Mosqueda, G. (author) / Reinhorn, A. M. (author)
Earthquake Engineering & Structural Dynamics ; 37 ; 21-42
2008-01-01
22 pages
Article (Journal)
Electronic Resource
English
Compensation of actuator delay and dynamics for real-time hybrid structural simulation
| Online Contents | 2008
Actuator dynamics compensation based on upper bound delay for real‐time hybrid simulation
| Online Contents | 2013
Development of Real-Time Hybrid Experimental System with Actuator Delay Compensation
| British Library Conference Proceedings | 1994