Finite Element Analysis. Barna Szabó
href="#ulink_18eaf7e5-97b7-58e5-9a4a-be8b7a5ce365">eq. (1.5) holds then for an arbitrary function , subject only to the restriction that all of the operations indicated in the following are properly defined, we have
Using the product rule;
we gettherefore eq. (1.17) is transformed to:
We introduce the following notation:
(1.19)
where
is a bilinear form. A bilinear form has the property that it is linear with respect to each of its two arguments. The properties of bilinear forms are listed Section A.1.3 of Appendix A. We define the linear form:The forcing function
may be a sum of forcing functions: , some or all of which may be the Dirac delta function4 multiplied by a constant. For example if thenThe properties of linear forms are listed in Section A.1.2. Note that
in eq. (1.21) is a linear form only if v is continuous and bounded.The definitions of
and are modified depending on the boundary conditions. Before proceeding further we need the following definitions.1 The energy norm is defined by(1.22) where I represents the open interval . This notation should be understood to mean that if and only if x satisfies the condition to the right of the bar (). This notation may be shortened to , or more generally where are real numbers. If the interval includes both boundary points then the interval is a closed interval denoted by .We have seen in the introductory example that the error is minimized in energy norm, that is, , equivalently is minimum. The square root is introduced so that (where α is a constant) holds. This is one of the definitive properties of norms listed in Section A.1.1.
2 The energy space, denoted by , is the set of all functions u defined on I that satisfy the following condition:(1.23) Since infinitely many linearly independent functions satisfy this condition, the energy space is infinite‐dimensional.
3 The trial space, denoted by , is a subspace of . When boundary conditions are prescribed on u, such as and/or , then the functions that lie in satisfy those boundary conditions. Note that when and/or then is not a linear space. This is because the condition stated under item 1 in Section A.1.1 is not satisfied. When u is prescribed on a boundary then that boundary condition is called an essential boundary condition. If no essential boundary conditions are prescribed on u then .
4 The test space, denoted by , is a subspace of . When boundary conditions are prescribed on u, such as and/or then the functions that lie in are zero in those boundary points.If no boundary conditions are prescribed on u then . If is prescribed and is not known then(1.24) (1.25) If is not known and is prescribed then(1.26) (1.27) If and are prescribed then(1.28) (1.29)
We are now in a position to describe the generalized formulation for various boundary conditions in a concise manner;
1 When u is prescribed on a boundary then the boundary condition is called essential or Dirichlet5 boundary condition. Let us assume that u is prescribed on both boundary points. In this case we write where is the function to be approximated and is an arbitrary fixed function that satisfies the boundary conditions. Substituting for u in eq. (1.18) we have:(1.30) and the generalized