Structural damage detection method based on random forests and data fusion

Abstract

A structural damage detection method by integrating data fusion and random forests was proposed. The original acceleration signals were translated into energy features by wavelet packet decomposition. Then the processed energy features were fused into new energy features by data fusion. This can further enlarge the differences among all types of damages. Finally, random forests as an effective classifier was used to detect the multiclass damage. Numerical study on the benchmark model and an eight-storey steel shear frame structure model was carried out to validate the accuracy of the proposed damage detection method. The experiment results indicate that the damage detection method based on random forests and data fusion can improve damage detection accuracy in comparison with random forests alone, support vector machine alone, and support vector machine and data fusion techniques. Moreover, the proposed method has significantly better stability than several other methods.

Keywords

Damage detection wavelet packet decomposition data fusion random forests support vector machine

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References

Kiremidjian

Straser

Law

. Structural damage monitoring for civil structures. In: International workshop on structural health monitoring, Stanford University, Stanford, CA, 18–20 September 1997.

Sohn

Farrar

Hemez

. A review of structural health monitoring literature: 1996–2001. Report LA-13976-MS, Los Alamos National Laboratory, Los Alamos, NM, 2003.

Han

Wang

. Overview of vibration based damage identification method. J S China Univ Tech 2003; 31(1): 91–96.

Farrar

Worden

Todd

. Nonlinear system identification for damage detection. Report LA-14351-MS, Los Alamos National Laboratory, Los Alamos, NM, 2007.

Farrar

Worden

. An introduction to structural health monitoring. Philos T R Soc A 2007; 365: 303–305.

Ghaboussi

Garrett

. Use of neural networks in detection of structural damage. Comput Struct 1992; 42(5): 649–659.

Pierce

Worden

Manson

. A novel information-gap technique to assess reliability of neural network-based damage detection. J Sound Vib 2006; 293: 96–111.

Kim

S-P

Kwak

H-G

. Structural damage evaluation using genetic algorithm. J Sound Vib 2011; 330: 2772–2783.

Worden

Lane

. Damage identification using support vector machines. Smart Mater Struct 2001; 10: 540–547.

10.

Worden

Manson

. The application of machine learning to structural health monitoring. Philos T R Soc Lond 2007; 365: 515–537.

11.

Meruane

Heylen

. Damage detection with parallel genetic algorithms and operational modes. Struct Health Monit 2010; 9(6): 481–496.

12.

Breiman

. Bagging predictors. Mach Learn 1996; 24(2): 123–140.

13.

Breiman

Friedman

Olshen

. Classification and regression trees. Cole/Wadsworth & Brooks, Belmont, California, USA, 1984.

14.

Breiman

. Random forests. Mach Learn 2004; 45(1): 5–32.

15.

Hall

. Mathematical techniques in multi-sensor data fusion. Boston, MA: Artech House, 1992.

16.

Mallat

. A wavelet tour of signal processing. San Diego, CA: Academic, 1998.

17.

Daubechies

. Ten lectures on wavelets. Philadelphia, PA: SIAM, 1992.

18.

Liggins

Hall

Llinas

. Multisensor data fusion: theory and practice. 2nd ed. CRC, Boca Raton, Florida, USA, 2008.

19.

20.

Bernal

Dyke

Lam

. Phase II of the IASC-ASCE benchmark study on SHM. In: Proceedings of the 15th ASCE engineering mechanics conference, Columbia University, New York, 2–5 June 2002.

21.

Lam

H-F

. Phase IIe of the IASC-ASCE benchmark study on structural health monitoring. In: Proceedings of the XXI international modal analysis conference, Kissimmee, FL, 3–6 February 2003.