Abstract
The paper presents k-version of the finite element method for boundary value problems (BVPs) and initial value problems (IVPs) in which global differentiability of approximations is always the result of the union of local approximations. The higher order global differentiability approximations (HGDA/DG) are always p-version hierarchical that permit use of any desired p-level without effecting global differentiability. HGDA/DG are true Ci, Cij, Cijk, hence the dofs at the nonhierarchical nodes of the elements are transformable between natural and physical coordinate spaces using calculus. This is not the case with tensor product higher order continuity elements discussed in this paper, thus confirming that the tensor product approximations are not true Ci, Cijk, Cijk approximations. It is shown that isogeometric analysis for a domain with more than one patch can only yield solutions of class C0. This method has no concept of finite elements and local approximations, just patches. It is shown that compariso of this method with k-version of the finite element method is meaningless. Model problem studies in R2 establish accuracy and superior convergence characteristics of true Cijp-version hierarchical local approximations presented in this paper over tensor product approximations. Convergence characteristics of p-convergence, k-convergence and pk-convergence are illustrated for self adjoint, non-self adjoint and non-linear differential operators in BVPs. It is demonstrated that h, p and k are three independent parameters in all finite element computations. Tensor product local approximations and other published works on k-version and their limitations are discussed in the paper and are compared with present work.
Highlights
The mathematical descriptions of the deformation of continuous media derived using conservation and balance laws of thermodynamics and associated constitutive theories lead to initial value problems (IVPs) or boundary values problems (BVPs)
In the k-version of the finite element method initiated by Surana et al [1,2,3], the authors showed that k, the order of the approximation space defining global differentiability of approximation over a discretization is an independent parameter in all finite element processes in addition to h and p, the terminology k-version of the finite element method in addition to h- and p-versions is quite natural
We considered the works of Surana et al [1,2,3,11,12,13,14,15,16,17,18,19,20,21] on k-version finite element method and have presented a unified computational methodology incorporating the k-version that addresses all higher order global differentiability issues in boundary value problems (BVPs) and IVPs
Summary
Initial value problems describe evolution, the dependent variables in their mathematical description exhibit simultaneous dependence on spatial coordinates and time. In case of boundary value problems that are stationary states of evolutions described by IVPs, the dependent variables only exhibit dependence on spatial coordinates. The shocks in compressible flow, if viewed at a bigger scale, may appear as a discontinuous phenomenon, but on closer examination at a finer scale these are continuous and differentiable. This basic assumption that solution of all BVPs and IVPs in physical sciences are generally analytic is the foundation of the work presented in this paper
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