International Journal of Software Computing and Testing

Open Access  Subscription or Fee Access

The vibration response data measured from the structure contains uncertainties and requires different techniques for its analysis. The present study involves the comprehensive review of the model based and data mining techniques which are frequently applied by various researchers in past to solve various multi criteria decision making and analysis problems. The selection of suitable technique for specific problem is required to obtain accurate outcomes. The literature survey is done to provide summary of articles with used data type, involved uncertainty type, and technique used. The uncertainty in the input data can be due to ambiguity, randomness, and partial information. The paper includes brief about Stochastic, Statistical and Computer based modeling techniques and Artificial Neural Networks (ANN), Fuzzy logic, Support vector machine (SVM), Bayesian classifiers (BC), and Cluster algorithms based data mining techniques. The advantages and disadvantages of each technique are also mentioned.

Martin Macho, Pavel Ryjacek, et al. Fatigue Life Analysis of Steel Riveted Rail Bridges Affected by Corrosion. Structural Engineering International. 2019;29(4)551–562.

John James Moughty and Joan R. Casas. A State of the Art Review of Modal-Based Damage Detection in Bridges : Development, Challenges, and Solutions. Applied Sciences. 2017;7(5):1-24.

Anshul Sharma, Pardeep Kumar, et al. Identification of Joint Discrepancy in Steel Truss Bridge Using Hilbert Transform with root-MUSIC and ESPRIT Techniques. International Journal of Civil Engineering. 2021;19:653-668.

J. Ko and Y. Ni. Technology developments in structural health monitoring of large-scale brides. Engineering Structures. 2005;27(12):1715–1725.

Zhang QW. Statistical damage identification for bridges using ambient vibration data. Computers & structures. 2007;85(7–8):476–485.

A.Deraemaekera, E.Reynders, et al. Vibration-based structural health monitoring using output only measurements under changing environment. Mechanical systems and signal processing. 2007;22(1):34–56.

MustafaGul and F.Necati Catbas. Statistical pattern recognition for structural health monitoring using time series modeling: theory and experimental verifications. Mechanical systems and signal processing. 2009;23(7):2192–2204.

Anshul Sharma, Pardeep Kumar, et al. Condition assessment of retrofitted steel truss bridge through fused Hilbert transform and frequency resolution enhancing techniques. Innovative Infrastructure Solutions. 2021;6(31):1-30.

Tao Yin , Hong-ping Zhu, et al. Noise analysis for sensitivity based structural damage detection. Applied Mathematics and Mechanics. 2007;28(6):741–750.

Charles R Farrar and Keith Worden. An introduction to structural health monitoring. Philosophical Transactions of the Royal Society A. 2007;365(1851):303–315.

Jingzhou Xin, Jianting Zhou, et al. Bridge structure deformation prediction based on GNSS data using kalman-ARIMA-GARCH model. Sensors (Basel). 2018;18(1):1–17.

Xiang Zhu, Maosen Cao, et al. Damage identification in bridges by processing dynamic responses to moving loads: Features and evaluation; Sensors (Basel). 2019;19(3):463.

Richard S. Pappa and S. R. Ibrahim. A parametric study of the Ibrahim time domain modal identification algorithm. 1986;24(3):499–503.

Walia Suresh Kumar, Patel Raj Kumar, et al. Joint discrepancy evaluation of an existing steel bridge using time-frequency and wavelet-based approach. International Journal of Advanced Structural Engineering. 2013;5(1):1–9.

Xiaohang Zhou, Lu Cao, et al. Data Inspecting and Denoising Method for Data-Driven Stochastic Subspace Identification. Shock and Vibration. 1–11; 2018.

P. J. Li, D. W. Xu, et al. Probability-Based Structural Health Monitoring Through Markov Chain Monte Carlo Sampling. International Journal of Structural Stability and Dynamics. 2016;16(7):1–16.

A.Sadhu, S.Narasimhan, et al. A review of output-only structural mode identification literature employing blind source separation methods. Mechanical Systems and Signal Processing. 2017;94:415–431.

Jiantao Li, Xinqun Zhu, et al. Indirect bridge modal parameters identification with one stationary and one moving sensors and stochastic subspace identification. Journal of Sound and Vibration. 2019;446:1–21.

Tian-Li Huang, Hao Zhou, et al. Stochastic modelling and optimum inspection and maintenance strategy for fatigue affected steel bridge members. Smart Structures and Systems. 2016;18(3):569-84.

An Yonghui, Ou Jinping, et al. Stochastic DLV method for steel truss structures: Simulation and experiment. Smart Structures and Systems. 2014;14(2):105–28.

Wei Zheng and Yi Yu. Bayesian probabilistic framework for damage identification of steel truss bridges under joint uncertainties. Advances in Civil Engineering. 2013.

Hamid Reza Ahmadi and Diana Anvari. New damage index based on least squares distance for damage diagnosis in steel girder of bridge’s deck. Structural Control and Health Monitoring. 2018;25(10):1–22.

Chaojun Huang and Satish Nagarajaiah. Experimental study on bridge structural health monitoring using blind source separation method: arch bridge. Structural Monitoring and Maintenance. 2015;1(1):69–87.

Hadi Kordestani, Yi-Qiang Xiang, et al. Application of the Random Decrement Technique in Damage Detection under Moving Load. Applied Sciences. 2018;8(5):753.

Yoshinao Goi & Chul-Woo Kim. Damage detection of a truss bridge utilizing a damage indicator from multivariate autoregressive model. Journal of Civil Structural Health Monitoring. 2017;7(2):153–62.

A. Ostermann, G. Spielberger, et al. Detecting structural changes with ARMA processes. Mathematical and Computer Modelling of Dynamical Systems. 2016;22(6):524–38.

Mosavi AA, Dickey D, et al. Identifying damage locations under ambient vibrations utilizing vector autoregressive models and Mahalanobis distances. Mechanical Systems and Signal Processing. 2012;26(1):254–267.

Chul-Woo Kim, Kai-Chun Chang, et al. A field experiment on a steel Gerber-truss bridge for damage detection utilizing vehicle-induced vibrations. Structural Health Monitoring. 2016;15(2):174–92.

Krzysztof Śledziewski. Fatigue assessment for selected connections of structural steel bridge components using the finite elements method. AIP Conference Proceedings. 2018;1922(1):1–11.

Lehua Wang and Gang Xu. Finite Element Analysis of Fire Behavior of Steel Girders in Bridges. Advanced Materials Research. 2012;594–597:2296–3000.

Maryam Mashayekhi and Erin Santini-Bell. Three-dimensional multiscale finite element models for in-service performance assessment of bridges. Computer-Aided Civil and Infrastructure Engineering. 2019;34(5):385–401.

Shankar Sehgal & Harmesh Kumar. Structural Dynamic Model Updating Techniques: A State of the Art Review. Archives of Computational Methods in Engineering. 2016;23(3):515–33.

Nizar Faisal Alkayem, Maosen Cao, et al. Structural damage detection using finite element model updating with evolutionary algorithms: a survey. Neural Computing and Applications.2018;30:389-411.

J.T. Wang, C.J. Wang, et al. Frequency response function-based model updating using Kriging model. Mechanical Systems and Signal Processing. 2017;87(Part A):218–28.

Masoud Sanayei, Ali Khaloo, et al. Automated finite element model updating of a scale bridge model using measured static and modal test data. Engineering Structures. 2015;102:66–79.

Leila Katebi, Mohsen Tehranizadeh, et al. A generalized flexibility matrix-based model updating method for damage detection of plane truss and frame structures. Journal of Civil Structural Health Monitoring. 2018;8(2):301–14.

Samim Mustafa and Yasunao Matsumoto. Bayesian Model Updating and Its Limitations for Detecting Local Damage of an Existing Truss Bridge. Journal of Bridge Engineering. 2017;22(7):1-14.

Lu Deng and C. S. Cai. Bridge Model Updating Using Response Surface Method and Genetic Algorithm. Journal of Bridge Engineering. 2010;15(5):553–564.

Shanglian Zhou and Wei Song. Environmental effects embedded model updating method considering environmental impacts. Structural Control and Health Monitoring. 2017;25(3):e2116.

Andre Jesus, Peter Brommer, et al. Modular Bayesian damage detection for complex civil infrastructure. Journal of Civil Structural Health Monitoring. 2019;9:201-215.

Meisam Gordan, Hashim Abdul Razak, et al. Recent Developments in Damage Identification of Structures Using Data Mining. Latin American Journal of Solids and Structures. 2017;14(13):2373–2401.

A. C. Neves, I. González, et al. Structural health monitoring of bridges: a model- free ANN-based approach to damage detection. Journal of Civil Structural Health Monitoring. 2017;7(5):689–702.

Jordan C. Weinstein, Masoud Sanayei, et al. Bridge Damage Identification Using Artificial Neural Networks. Journal of Bridge Engineering. 2018;23(11):1–13.

Yuequan Bao, Zhicheng Chen, et al. The State of the Art of Data Science and Engineering in Structural Health Monitoring. Engineering. 2019;5(2):234–42.

M. Mehrjoo, N. Khaji, et al. Damage detection of truss bridge joints using Artificial Neural Networks. Expert Systems with Applications. 2008;35(3):1122–1131.

Branislav Kostić and Mustafa Gül. Vibration-Based Damage Detection of Bridges under Varying Temperature Effects Using Time-Series Analysis and Artificial Neural Networks. Journal of Bridge Engineering. 2017;22(10):1–16.

S.J.S. Hakim and H. Abdul Razak. Application of artificial neural network on vibration test data for damage identification in bridge girder. International Journal of the Physical Sciences. 2011;6(35):7991–8001.

Jong-Jae Lee & Chung-Bang Yun. Damage localization for bridges using probabilistic neural networks. KSCE Journal of Civil Engineering. 2007;11(2):111–20.

Ghosh-Dastidar, S; Adeli, H; Third Generation Neural Networks: Spiking Neural Networks. Advances in Computational Intelligence. 2009;116:167–78.

Tao Yin and Hong-ping Zhu. Probabilistic Damage Detection of a Steel Truss Bridge Model by Optimally Designed Bayesian. Sensors. 2018;18(10):1–16.

Osama Abdeljaber, Onur Avci, et al. Real-time vibration-based structural damage detection using one-dimensional convolutional neural networks. Journal of Sound and Vibration. 2017;388:154–70.

Haiyang Zhang, Mustafa Gül, et al. Eliminating Temperature Effects in Damage Detection for Civil Infrastructure Using Time Series Analysis and Autoassociative Neural Networks. Journal of Aerospace Engineering. 2019;32(2):1–16.

Hassan Aghabarati and Mohsen Tabrizizadeh. Comparison Study on Neural Networks in Damage Detection of Steel Truss Bridge. Journal of structural engineering and geotechnics. 2011;1(1):37–48.

Cao Vu Dung, Hidehiko Sekiya, et al. A vision-based method for crack detection in gusset plate welded joints of steel bridges using deep convolutional neural networks. Automation in Construction. 2019;102:217–29.

Yu-Bo Jiao, Han-Bing Liu, et al. Damage Identification of Bridge Based on Chebyshev Polynomial Fitting and Fuzzy Logic without Considering Baseline Model Parameters. Shock and Vibration frequency. 1–11; 2015.

Ling Yu, Jun-Hua Zhu, et al. Structural Damage Detection in a Truss Bridge Model Using Fuzzy Clustering and Measured FRF Data Reduced by Principal Component Projection. Advances in Structural Engineering. 2013;16(1):207–17.

P. J. Escamilla-Ambrosio, X. Liu, et al. Wavelet-fuzzy logic approach to structural health monitoring. Annual Meeting of the North American Fuzzy Information Processing Society. 18-20 March 2011; El Paso, TX, USA, New York: IEEE; 2011.

Ramin Ghiasi, Peyman Torkzadeh, et al. A machine-learning approach for structural damage detection using least square support vector machine based on a new combinational kernel function. Structural Health Monitoring. 2016;15(3):1–15.

Hassene Hasni, Amir H.Alavi, et al. Detection of fatigue cracking in steel bridge girders : A support vector machine approach. Archives of Civil and Mechanical Engineering. 2017;17(3):609–622.

Seyed Sina Kourehli. Prediction of unmeasured mode shapes and structural damage detection using least squares support vector machine. Structural Monitoring and Maintenance. 2018;5(3):379–90.

Seyed Yadavar Nikravesh, Hossein Rezaie, et al. Intelligent Fault Diagnosis of Bearings Based on Energy Levels in Frequency Bands Using Wavelet and Support Vector Machines (SVM). Journal of Manufacturing and Materials Processing. 2019;3(11):1–14.

Meisam Gordan, Zubaidah Ismail, et al. Data mining-based damage identification of a slab-on-girder bridge using inverse analysis. Measurement. 2019;151:107175.

Xiaomo Jiang, and Sankaran Mahadevan. Bayesian Probabilistic Inference for Nonparametric Damage Detection of Structures. Journal of Engineering Mechanics. 2008;134(10):820–31.

Chul-Woo Kim, Yi Zhang, et al. Long-term bridge health monitoring and performance assessment based on a Bayesian approach. Structure and Infrastructure Engineering. 2018;14(7):1–12.

Shuang Sun, Li Liang, et al. Bridge Performance Evaluation via Dynamic Fingerprints and Data Fusion. Journal of Performance of Constructed Facilities. 2019;33(2):1–12.

Alberto Diez, Nguyen Lu Dang Khoa, et al. A clustering approach for structural health monitoring on bridges. Journal of Civil Structural Health Monitoring. 2016;6:429-445.

Yongping Zeng, Yongyi Yan, et al. Fuzzy clustering of time-series model to damage identification of structures. Advances in Structural Engineering. 2019; 22(4):1 -14.

Michele Dilena and Antonino Morassi. Dynamic testing of damaged bridge. Mechanical systems and signal processing. 2011;25(5):1485 -1507.