Sage Journals: Discover world-class research

Abstract

This article investigates a closed-loop control method for multi-input multi-output (MIMO) non-Gaussian random vibration testing. Unlike Gaussian vibration scenarios, the challenge lies in rapidly generating non-Gaussian random signals with specified power spectral density (PSD), skewness, and kurtosis. Although the original phase selection method (OPSM) can perfectly achieve such requirement, its high computational complexity and limited real-time performance hinder the application in the MIMO vibration testing, due to numerous parameters. To deal with this, a rapid phase selection method (RPSM) is proposed, based on the OPSM. The RPSM simplifies the parameters into two core variables. Specifically, for PSD with 400 spectral lines, RPSM can reduce the parameters from 400 variables to 2, corresponding to 99.5% dimensionality reduction. Based on the RPSM, a closed-loop control method is formulated according to the deviations between the responses and references. It can control the PSD profiles, skewness, and kurtosis of all control channels within the specified tolerances. Experimental results from biaxial vibration testing demonstrate the effectiveness of the proposed methodology.

Keywords

phase selection method multi-input multi-output skewness kurtosis power spectral density

Get full access to this article

View all access options for this article.

References

Benasciutti

Tovo

(2006) Fatigue life assessment in non-Gaussian random loadings. International Journal of Fatigue 28: 733–746.

Cui

Chen

(2017) Time-domain approach for multi-exciter random environment test. Journal of Sound and Vibration 398: 52–69.

Cui

Chen

, et al. (2018) Control algorithm update for multi-input multi-output random environment test. Mechanical Systems and Signal Processing 111: 643–662.

Daborn

Ind

Ewins

(2014) Enhanced ground-based vibration testing for aerodynamic environments. Mechanical Systems and Signal Processing 49: 165–180.

Falsone

Settineri

(2011) A method for the random analysis of linear systems subjected to non-stationary multi-correlated loads. Probabilistic Engineering Mechanics 26(3): 447–453.

Chen

Zheng

(2022) Control strategy for multi-axial swept sine on random mixed vibration testing. Journal of Sound and Vibration 527: 116846.

Chen

, et al. (2023) Half sine shock on random control method for multi-axial vibration testing. Journal of Vibration and Control 29(13–14): 2995–3005.

Manring

Schultze

Zimmerman

, et al. (2023) Improving convergence of the matrix power control algorithm for random vibration testing. Mechanical Systems and Signal Processing 182: 109574.

MIL-STD-810H (2019) Department of Defense Test Method Standard for Environmental Engineering Considerations and Laboratory Tests. United States Department of Defense.

10.

Musella

D’Elia

Carrella

, et al. (2018) A minimum drives automatic target definition procedure for multi-axis random control testing. Mechanical Systems and Signal Processing 107: 452–468.

11.

Palmieri

Cesnik

Slavic

, et al. (2017) Non-Gaussianity and non-stationarity in vibration fatigue. International Journal of Fatigue 97: 9–19.

12.

Roberts

Ewins

(2018) Multi-axis vibration testing of an aerodynamically excited structure. Journal of Vibration and Control 24(2): 427–437.

13.

Sarkani

Kihl

Beach

(1994) Fatigue of welded joints under narrowband non-Gaussian loadings. Probabilistic Engineering Mechanics 9(3): 179–190.

14.

Sheng

Fan

Yang

, et al. (2022) Auxiliary harmonic excitation generalized method for random vibration analysis of linear structures under non-stationary Gaussian excitation. Mechanical Systems and Signal Processing 172: 108958.

15.

Smallwood

(1997) Generation of stationary non-Gaussian time histories with a specified cross-spectral density. Shock and Vibration 4(5–6): 361–377.

16.

Smallwood

(2005) Generating non-Gaussian vibration for testing purposes. Sound and Vibration 39(10): 18–23.

17.

Smallwood

(2007) Multiple-input multiple-output (MIMO) linear systems extreme inputs/outputs. Shock and Vibration 14: 107–131.

18.

Steinwolf

(2012) Random vibration testing with kurtosis control by IFFT phase manipulation. Mechanical Systems and Signal Processing 28: 561–573.

19.

Steinwolf

Cornelis

Peeters

, et al. (2020) On the use of kurtosis control methods in shaker testing for fatigue damage. Journal of Testing and Evaluation 48(1): 538–556.

20.

Underwood

Keller

(2001) Recent system developments for multi-actuator vibration control. Sound and Vibration 35: 16–23.

21.

Winterstein

(1988) Nonlinear vibration models for extremes and fatigue. Journal of Engineering Mechanics 114(10): 1772–1790.

22.

Zheng

Chen

(2017) Control method for multi-input multi-output non-Gaussian random vibration test with cross spectra consideration. Chinese Journal of Aeronautics 30(6): 1895–1906.

23.

Zheng

Chen

, et al. (2018) Probability distributions control for multi-input multi-output stationary non-Gaussian random vibration test. Journal of Vibration and Control 24(21): 5201–5210.

24.

Zheng

Chen

(2021) Stationary non-Gaussian random vibration control: a review. Chinese Journal of Aeronautics 34(1): 350–363.

Rapid phase selection method for MIMO closed-loop vibration control with non-Gaussian signal shaping

Abstract

Keywords

Get full access to this article

References