Optimization of Functionally Graded Beams Resting on Elastic Foundations
Subject Areas : EngineeringM.H Yas 1 , S Kamarian 2 , J.E Jam 3 , A Pourasghar 4
1 - Department of Mechanical Engineering, Razi University, Kermanshah
2 - Department of Mechanical Engineering, Razi University, Kermanshah
3 - Center for Composite Materials & Structures, MUT, Tehran
4 - Department of Mechanical Engineering, Razi University, Kermanshah
Keywords:
Abstract :
[1] Francesco Tornabene., Erasmo Viola., 2009, Free vibrations of three-parameter functionally graded parabolic panels of revolution, Mechanics research communications 36: 587-594.
[2] Zhou Ding., 1993, A general solution to vibrations of beams on variable Winkler elastic foundation, Computers and structures 47: 83-90.
[3] Thambiratnam D., Zhuge Y., 1996, Free vibration analysis of beams on elastic foundation, Computers and Structures 60(6): 971–980.
[4] Matsunaga H., 1999, Vibration and buckling of deep beam–columns on two-parameter elastic foundations, Journal of Sound and Vibration 228(2): 359-376.
[5] Ying J., Lu C.F., Chen W.Q., 2008, Two-dimensional elasticity solutions for functionally graded beams resting on elastic foundations, Composite Structures 84: 209-219.
[6] Pradhan S.C., Murmu T., 2009, Thermo-mechanical vibration of FGM sandwich beam under variable elastic foundations using differential quadrature method, Journal Sound and Vibration 321: 342-362.
[7] Abouhamze M., Shakeri M., 2007, Multi-objective stacking sequence optimization of laminated cylindrical panels using a genetic algorithm and neural networks, Composite Structures 81(2): 253-263.
[8] Apalak MK., Yildirim M., Ekici R., 2008, Layer optimization for maximum fundamental frequency of laminated composite plates for different edge conditions, Composite Science and Technology 68: 537-50.
[9] Walker M., Smith R., 2003, A technique for the multi objective optimization of laminated composite structures using genetic algorithms and finite element analysis, Composite Structures 62(1): 123-128.
[10] Soremekun G., Gurdal Z., Haftka RT., Watson LT., 2001, Composite laminate design optimization by genetic algorithm with generalized elitist selection, Composite Structures 79: 131-143.
[11] Anderson D., Hines EL., Arthur SJ., Eiap EL., 1997, Application of artificial neural networks to the prediction of minor axis steel connections, Computers and Structures 63(4): 685-692.
[12] Ootao Y., Tanigawa Y., Nakamura T., 1999, Optimization of material composition of FGM hollow circular cylinder under thermal loading: a neural network approach, Composites Part B: Engineering 30: 415-422.
[13] Han X., Xu D., Liu G.R., 2003, A computational inverse technique for material characterization of a functionally graded cylinder using a progressive neural network, Neurocomputing 51: 341-360.
[14] Jodaei A., Jalal M., Yas M.H., 2011, Free vibration analysis of functionally graded annular plates by state-space based differential quadrature method and comparative modeling by ANN, Composites Part B: Engineering 43(2): 340-353.
[15] Bellman R., Kashef B.G., Casti J., 1972, Differential quadrature: a technique for a rapid solution of non linear partial differential equations, Journal of Computational Physics 10: 40-52.
[16] Shu C., 2000, Differential Quadrature and Its Application in Engineering, Berlin, Springer.
[17] Shu C., Richards BE., 1992, Application of generalized differential quadrature to solve two-dimensional incompressible Navier Stockes equations, International Journal for Numerical Methods in Fluids 15: 791-798.
[18] Haftka RT., Gurdal Z., 1992, Elements of Structural Optimization, Third edition, Kluwer.
[19] Gurdal Z., Haftka R.T., Hajela, 1999, Design and Optimization of Laminated Composite Materials, Wiley, Interscience.
[20] Shakeri M.,Akhlaghi M., Hoseini S.M.,2006,Vibration and radial wave propagation velocity in functionally graded thick hollow cylinder, Composite Structures 76(1-2):174-181.
