论文信息 - Application of artificial neural networks to evaluation of ultimate strength of steel panels

Application of artificial neural networks to evaluation of ultimate strength of steel panels

Abstract Structural design of ships and offshore structures has been moving towards limit state design or reliability-based design. Improving the accuracy and efficiency of predicting the ultimate strength of structural components, such as unstiffened panels and stiffened panels, has a significant impact on our daily structural design. Empirical formulations have been widely used because of their simplicity and reasonable accuracy. In the past, empirical formulations were generally developed by using regression analysis. The model uncertainties of good empirical formulations are around 10%–15% in terms of coefficients of variation. In this paper, artificial neural networks (ANN) methodology is applied to predict the ultimate strength of unstiffened plates under uni-axial compression. The proposed ANN models are trained and cross-validated using the existing experimental data. Different ways to construct ANN models are also explored. It is found that ANN models can produce a more accurate prediction of the ultimate strength of panels than the existing empirical formulae. The ANN model with five (original) input variables has slightly better accuracy than the model with three input variables. This demonstrates the capacity of the ANN method to establish successfully a functional relationship between input and output parameters.

Yongchang Pu | Ehsan Mesbahi | E. Mesbahi | Y. Pu

[1] Yoshisada Murotsu,et al. Structural Reliability Analysis Using a Neural Network. , 1997 .

[2] Yongchang Pu,et al. Prediction of Ultimate Capacity of Perforated Lipped Channels , 1999 .

[3] D. Faulkner,et al. Synthesis of welded grillages to withstand compression and normal loads , 1973 .

[4] Dong Wei,et al. Ultimate Compressive Strength Prediction of Stiffened Panels By Counterpropagation Neural Networks (CPN) , 1999 .

[5] Jose C. Principe,et al. Neural and adaptive systems , 2000 .

[6] Yongchang Pu. Reliability Analysis and Reliability-Based Optimisation Design of SWATH Ships , 1995 .

[7] C. Bucher,et al. A fast and efficient response surface approach for structural reliability problems , 1990 .

[8] Yukio Ueda,et al. Ultimate strength of square plates subjected to compression (1st Report) , 1975 .

[9] D. Faulkner. A REVIEW OF EFFECTIVE PLATING TO BE USED IN THE ANALYSIS OF STIFFENED PLATING IN BENDING AND COMPRESSION , 1973 .

[10] Preben Terndrup Pedersen,et al. Strength of ship plates under combined loading , 2002 .

[11] Jeom Kee Paik,et al. Advanced ultimate strength formulations for ship plating under combined biaxial compression/tension, edge shear, and lateral pressure loads , 2001 .

[12] C. Guedes Soares,et al. Design equation for the compressive strength of unstiffened plate elements with initial imperfections , 1988 .

[13] C A Carlsen,et al. SIMPLIFIED COLLAPSE ANALYSIS OF STIFFENED PLATES , 1977 .