Prediction of Unmeasured Mode Shape Using Artificial Neural Network for Damage Detection
DOI:
https://doi.org/10.11113/jt.v61.1624Keywords:
Artificial neural network, cubic spline, mode shape, damage detectionAbstract
Artificial neural networks (ANNs) have received much attention in the field of vibration–based damage detection since the 1990s, due to their capability to predict damage from modal data. However, the accuracy of this method is highly dependent on the number of measurement points, especially when the mode shape is used as an indicator for damage detection. With a high number of measurement points, more information can be fed to the ANN to detect damage; therefore, more reliable results can be obtained. Nevertheless, in practice, it is uneconomical to install sensors on every part of a structure; thus the capability of ANNs to detect damage is quite limited. In this study, an ANN is applied to predict the unmeasured mode shape data based on a limited number of measured data. To demonstrate the accuracy of the proposed method, the results are compared with the Cubic Spline interpolation (CS) method. A parametric study is also conducted to investigate the sensitivity of the number of measurement points to the proposed method. The results show that the ANN provides more reliable results compared to the CS method as it is able to predict the magnitude of mode shapes at the unmeasured points with a limited number of measurement points. The application of a two–stage ANN showed results with a high potential for overcoming the issue of using a limited number of sensors in structural health monitoring.References
S. W. Doebling, C. R. Farrar, M. B. Prime, D. W. Shevitz. 1996. Damage Identification and Health Monitoring of Structural and Mechanical Systems from Changes in Their Vibration Characteristics: A Literature Review. In Los Alamos National Laboratory Report, LA-13070-MS.
H. Sohn, C. R. Farrar, F. Hemez, J. Czarnecki. 2003. A Review of Structural Health Monitoring Literature: 1996-2001. In Los Alamos National Laboratory Report. LA-13976-MS.
J. Li, J. Wang, S. L. J. Hu. 2008. Using Incomplete Modal Data for Damage Detection in Offshore Jacket Structures. Ocean Engineering. 35: 1793–1799.
Q. W. Yang, J. K. Liu. 2007. Structural Damage Identification Based on Residual Force Vector. Journal of Sound and Vibration. 305: 298–307.
F. T. K. Au, Y. S. Cheng, L. G. Tham, Z. Z. Bai. 2003. Structural Damage Detection Based on a Micro-genetic Algorithm Using Incomplete and Noisy Modal Test Data. Journal of Sound and Vibration. 259: 1081–1094.
S. S. Law, T. H. T. Chan, D. Wu. 2001. Efficient Numerical Model for the Damage Detection of Large Scale. Engineering Structures. 23: 436–451.
M. Merhjoo, N. Khaji, H. Moharrami, A. Bahreininejad. 2008. Damage Detection of Truss Bridge Joints Using Artificial Neural Networks. Expert Systems with Application. 35: 1122–1131.
C. B. Yun, E. Y. Bahng. 2000. Substructural Identification Using Neural Networks. Computers & Structures. 77: 41–52.
B. Xu. 2006. Neural Networks Based Structural Model Updating Methodology Using Spatially Incomplete Accelerations. In: L. Jiao, (Ed.). International Conference on Natural Computation, Springer-Verlag. 361–370.
J. Carvalho, B. N. Datta, A. Gupta, M. Lagadapati. 2007. A Direct Method for Model Updating with Incomplete Measured Data and Without Spurious Modes. Mechanical Systems and Signal Processing. 2: 2715–2731.
N. Bakhary, H. Hao, A. J. Deeks. 2010. Structure Damage Detection Using Neural Network with Multi-Stage Substructuring. Advances in Structural Engineering. 13: 95–110.
E. Parloo, S. Vanlanduit, P. Guillaume, P. Verboven. 2004. Increased Reliability of Reference-based Damage Identification Techniques by Using Output-Only Data. Journal of Sound and Vibration. 270: 813–832.
M. Meo, G. Zumpano. 2005. On the optimal sensor placement tehcniques for a bridge structure. Engineering Structures. 27: 1488-1497.
L. J. Hadjileontiadisa, E. Douka. 2007. Crack detection in plates using fractal dimension. Engineering Structures. 29: 1612–1625.
T. H. Ooijevaar, R. Loendersloot, L. L. Warnet, A. d. Boer, R. Akkerman. 2010. Vibration Based Structural Health Monitoring of a Composite T-beam. Composite Structures. 92: 2007–2015.
S. Loutridisa, E. Douka, A. Trochidis. 2004. Crack Identification in Double-cracked Beams Using Wavelet Analysis. Journal of Sound and Vibration. 277: 1025–1039.
M. Rucka, K. Wilde. 2006. Application of Continuous Wavelet Transform in Vibration Based Damage Detection Method for Beams And Plates. Journal of Sound and Vibration. 297: 536–550.
W. L. Bayissaa, N. Haritosa, S. Thelandersson. 2008. Vibration-based Structural Damage Identification Using Wavelet Transform. Mechanical Systems and Signal Processing. 22: 1194–1215.
M. Radzienski, M. Krawczuk, M. Palacz. 2011. Improvement of Damage Detection Methods Based on Experimental Modal Parameters. Mechanical Systems and Signal Processing. 25: 2169–2190.
J. Rhim, S. W. Lee. 1995. A Neural Network Approach for Damage Detection and Identification Of Structures. Computational Mechanics. 16: 437–443.
P. C. Pandey, S. V. Barai. 1995. Multilayer Perceptron in Damage Detection of Bridge Structures. Computers & Structures. 54: 597–608.
S. F. Masri, M. Nakamura, A. G. Chassiakos, T. K. Caughey. 1996. Neural Network Approach to Detection of Changes in Structural Parameters. Journal of Engineering Mechanics. 122: 350–360.
J. Zhao, J. N. Ivan, J. T. Dewolf. 1998. Structural Damage Detection Using Artificial Neural Networks. Journal of Infrastructure Systems. 4: 93–101.
C. Gonzalez-Perez, J. Valdes-Gonzalez. 2011. Identification Of Structural Damage in a Vehicular Bridge Using Artificial Neural Networks. Structural Health Monitoring. 10: 33–48.
B. S. Wang, Z. C. He. 2007. Crack Detection of Arch Dam Using Statistical Neural Network Based on the Reductions of Natural Frequencies. Journal of Sound and Vibration. 302: 1037–1047.
S. McKinley, M. Levine. 2011. Cubic spline interpolation, in http://online.redwoods.cc.ca.us/instruct/darnold/laproj/Fall98/SkyMeg/Proj.PDF. 5 August 2011.
N. Bakhary. 2010. Statistical Vibration Based Damage Identification Using Artificial Neural Network. Jurnal Teknologi. 52: 49–60.
Downloads
Published
Issue
Section
License
Copyright of articles that appear in Jurnal Teknologi belongs exclusively to Penerbit Universiti Teknologi Malaysia (Penerbit UTM Press). This copyright covers the rights to reproduce the article, including reprints, electronic reproductions, or any other reproductions of similar nature.