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http://dx.doi.org/10.3744/SNAK.2015.52.1.88

Development of a Fatigue Damage Model of Wideband Process using an Artificial Neural Network  

Kim, Hosoung (Department of Naval Architecture and Ocean Engineering, College of Engineering, Inha University)
Ahn, In-Gyu (Department of Naval Architecture and Ocean Engineering, College of Engineering, Inha University)
Kim, Yooil (Department of Naval Architecture and Ocean Engineering, College of Engineering, Inha University)
Publication Information
Journal of the Society of Naval Architects of Korea / v.52, no.1, 2015 , pp. 88-95 More about this Journal
Abstract
For the frequency-domain spectral fatigue analysis, the probability density function of stress range needs to be estimated based on the stress spectrum only, which is a frequency domain representation of the response. The probability distribution of the stress range of the narrow-band spectrum is known to follow the Rayleigh distribution, however the PDF of wide-band spectrum is difficult to define with clarity due to the complicated fluctuation pattern of spectrum. In this paper, efforts have been made to figure out the links between the probability density function of stress range to the structural response of wide-band Gaussian random process. An artificial neural network scheme, known as one of the most powerful system identification methods, was used to identify the multivariate functional relationship between the idealized wide-band spectrums and resulting probability density functions. To achieve this, the spectrums were idealized as a superposition of two triangles with arbitrary location, height and width, targeting to comprise wide-band spectrum, and the probability density functions were represented by the linear combination of equally spaced Gaussian basis functions. To train the network under supervision, varieties of different wide-band spectrums were assumed and the converged probability density function of the stress range was derived using the rainflow counting method and all these data sets were fed into the three layer perceptron model. This nonlinear least square problem was solved using Levenberg-Marquardt algorithm with regularization term included. It was proven that the network trained using the given data set could reproduce the probability density function of arbitrary wide-band spectrum of two triangles with great success.
Keywords
Spectral fatigue analysis; Wideband process; Probability density function; Artificial neural network; Rainflow counting; Least square;
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