Finite Element Approximation for Optimal Shape Design: Theory and ApplicationsExplains how to speed the optimal shape design process using a computer. Outlines the problems inherent in optimal shape design and discusses methods of their solution. Concentrates on finite element approximation and describes numerical realization of optimization techniques. Treats optimal design problems via the optimal control theory when the state systems are governed by variational inequalities. Provides useful background information, followed by numerous approaches to optimal shape design, all supported by illustrative examples. Appendices provide algorithms and numerous examples and their calculations are included. |
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Page 53
... boundary value state problem scalar case - 3.1 . Existence result Here we shall apply the general theory , presented in Chapter 2 , Section 2.1 , to a case where the state relation is given by a simple unilateral boundary value problem ...
... boundary value state problem scalar case - 3.1 . Existence result Here we shall apply the general theory , presented in Chapter 2 , Section 2.1 , to a case where the state relation is given by a simple unilateral boundary value problem ...
Page 106
... boundary value problem . The moving part of the boundary will need to be designed in such a way that the flux across it attains its minimum . 6.1 . Setting of the problem Let ( a ) C R2 , a € Uad be given by ( 3.1 ) . The partition of ...
... boundary value problem . The moving part of the boundary will need to be designed in such a way that the flux across it attains its minimum . 6.1 . Setting of the problem Let ( a ) C R2 , a € Uad be given by ( 3.1 ) . The partition of ...
Page 158
... boundary conditions assumed on IN ( a ; ) . Type of boundary u = ( u1 , u2 ) = 0 u1 = 0 , T2 ( u ) = 0 part Γι г1 , P u1 pl Γρ T ( u ) = ri ( a ) Boundary condition p0 ( 0,0 ) , j = 0 = = ( p , -p ) , j = 1 p2 = ( 0 , −p ) , j = 2 p3 ...
... boundary conditions assumed on IN ( a ; ) . Type of boundary u = ( u1 , u2 ) = 0 u1 = 0 , T2 ( u ) = 0 part Γι г1 , P u1 pl Γρ T ( u ) = ri ( a ) Boundary condition p0 ( 0,0 ) , j = 0 = = ( p , -p ) , j = 1 p2 = ( 0 , −p ) , j = 2 p3 ...
Contents
Preliminaries | 1 |
Abstract setting of optimal shape design problem and | 28 |
Optimal shape design of systems governed by a unilateral | 53 |
Copyright | |
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adjoint algorithm Appendix applied approximation boundary value problem C₁ Céa compute constraints contact problems convex convex set cost functional defined denote design sensitivity analysis differentiable discrete domain elastic exist a subsequence Figure Find finite element follows formula given Gm(a H¹(Î Haslinger Haug Hlaváček I₁ Ir(an ITERATION jEJk Komkov Lagrange multipliers least one solution Lemma lim inf lim sup linear Lipschitz Lipschitz continuous lower semicontinuous mapping material derivative matrix method minimization Nečas Neittaanmäki nodes nonlinear nonlinear programming nonsmooth Numerical results obtain optimal control optimal design optimal pair optimal shape design parameter Pironneau Proof results for Example Section sensitivity analysis sequence shape design problems Shape optimization Sokolowski solves P(a subgradient subset T₁ Theorem triangulation un(an unilateral boundary value variational inequality vector w₁ Zolesio г₁