Advances in Real-Time Hybrid Testing Technology for Shaking Table Substructure Testing

Tian, Yingpeng; Shao, Xiaoyun; Zhou, Huimeng; Wang, Tao

doi:10.3389/fbuil.2020.00123

Cited by 14 publications

(10 citation statements)

References 81 publications

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“…The nonconvergent second half oscillates a lot and causes a large RMS error. In iteration 9, 𝐚 9 𝑁 and 𝐚 9 𝐸 were very similar and the iteration converged. As shown in Figure 9C, 𝐚 𝑝 𝑁 and 𝐚 𝑝 𝐸 converged to become perfectly identical in simulation.…”

Section: Resultsmentioning

confidence: 90%

“…The experimental substructure was subjected to high‐rate real‐time loading in RTHT, and its accurate dynamic response was obtained. Notably, RTHT can be conducted with servo‐hydraulic actuators, 7 shaking tables, 8 or a combination of the two 9 . To conduct RTHT, three problems must be properly addressed: (1) the computation of the numerical substructures should be efficient and stable; (2) the loading of the experimental substructure should be accurate and have low latency; (3) the communication between the substructures should be synchronized and have a small time delay.…”

Section: Introductionmentioning

confidence: 99%

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Time history iteration algorithm for offline real‐time hybrid testing

Guo,

Wang,

Pan

2023

Earthq Engng Struct Dyn

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Real‐time hybrid testing (RTHT) is a reliable and efficient method for large‐scale dynamic testing. Unlike online RTHT, offline RTHT allows the computation of the numerical substructure independent of the loading of the experimental substructure, which has obvious advantages in terms of accuracy, stability, and cost. The existing offline RTHT method is difficult to converge in many cases and has a limited range of applications. This paper proposes a new time history iteration (THI) algorithm based on cumulative increments. The increment of the next iteration signal is determined based on the increments of all previous iteration signals. The proposed algorithm can improve the system stability and convergence speed of offline RTHT. The stabilization mechanism and effect of the key parameter were investigated by conducting a series of simulations. Physical tests were performed on structures equipped with a tuned mass damper and an active mass damper. The test results suggest that the proposed THI algorithm can simultaneously consider iterations at all time steps and solve the coupling problem in offline RTHT. The time history iteration is stable and always converges in tests when facing complex situations such as resonance, nonlinearity, closed‐loop control, and measurement noise.

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Section: Resultsmentioning

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Time history iteration algorithm for offline real‐time hybrid testing

Guo,

Wang,

Pan

2023

Earthq Engng Struct Dyn

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“…With over 2 decades of dedicated research focusing on integration algorithms, delay compensation, and evaluation methods, RTHS has emerged as an effective and efficient technique for performance evaluation of systems under earthquakes. Its capability to facilitate real-time, large-scale testing has significantly contributed to the evaluation and validation of technologies for seismic hazard mitigation, marking a pivotal milestone in the field of earthquake engineering (Nakashima et al, 1992;Ou et al, 2015;Tian et al, 2020;Li et al, 2022;Palacio-Betancur and Soto, 2023).…”

Section: Introductionmentioning

confidence: 99%

Evaluation of data-driven NARX model based compensation for multi-axial real-time hybrid simulation benchmark study

Xu,

Meng,

Chen

et al. 2024

Front. Built Environ.

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Actuator control takes a pivotal role in achieving stability and accuracy, particularly in the context of multi-axial real-time hybrid simulation (maRTHS). In maRTHS, multiple hydraulic actuators are necessitated to apply precise motions to experimental substructures thus necessitating the application of multiple-input multiple-output (MIMO)control strategies. This study evaluates the data-driven nonlinear autoregressive with external input (NARX) based compensation for the servo-hydraulic dynamics within the maRTHS benchmark model. Different from previous study, nonlinear terms are incorporated into the NARX model. Online least square and ridge regression techniques are utilized to estimate the model coefficients to achieve optimal compensation. The influence of various model order and window length is assessed for the NARX model-based compensation. The findings of this research demonstrate that NARX-based compensation has significant potential not only in facilitating precise actuator control for maRTHS but also in enabling robust control in the presence of unknown uncertainties inherent to the servo-hydraulic system.

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“…The lower part of the tower is subject to strong forces and moments and is more easily damaged during an earthquake or a period of high wind loads. However, testing the lower part of a tower in STST is difficult because of the complex dynamic force coordination on the boundary between numerical and physical substructures (Tian et al, 2020b). A hydraulic actuator is often employed to realize boundary compatibility between numerical and physical substructures.…”

Section: Introductionmentioning

confidence: 99%

Reproduction of seismic responses of wind turbine tower by hybrid tests considering shear and bending coupled boundary control

Tian

Wang

Zhou

2022

Advances in Structural Engineering

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The dynamic responses of wind turbine towers subjected to earthquakes and winds are very complex and might cause significant damages. However, the reproduction of the dynamic response in a laboratory is not easy because the specimen shall be scaled very small to meet the space limits of wind tunnels and shaking tables. Real-time hybrid testing (RTHT) is an appealing option to solve this difficulty, which takes part of a structure as the specimen, while treats the rest numerically so that large scale specimen could be used. However, the application of RTHT to a wind turbine tower requires more complex boundary coordination to reproduce the coupled shear and bending behavior. This paper proposes a shaking-table substructure testing framework, where the lower part of the tower is fixed on the shaking table at the bottom and the top of the specimen is simultaneously loaded by a two-degree-of-freedom loading device. The loading facilities communicate in real time with the numerical substructure, and the superstructure including the wind turbine and blades is numerically simulated under the external excitations. Displacements and forces at the boundary are transferred between the numerical and physical substructures to realize boundary compatibility and equilibrium. A novel boundary loading device controls two masses to realize bending and shear equilibrium at the same boundary surface. Enhanced three-variable control is proposed to improve the performance of boundary coordination and the error-response negative feedback compensation method is proposed to reduce error transmission in RTHT, as demonstrated and introduced in a series of simulations and conceptual study.

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Advances in Real-Time Hybrid Testing Technology for Shaking Table Substructure Testing

Cited by 14 publications

References 81 publications

Time history iteration algorithm for offline real‐time hybrid testing

Time history iteration algorithm for offline real‐time hybrid testing

Evaluation of data-driven NARX model based compensation for multi-axial real-time hybrid simulation benchmark study

Reproduction of seismic responses of wind turbine tower by hybrid tests considering shear and bending coupled boundary control

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