Femlib

Library for Finite Element Method
Note: This page is under construction

Abstract

Table of Contents [TOC]

Terminology

Introduction

This document defines functionality and interface of FemLib in OGS6. Primary role of the library is to provide users means to discretize mathematical equations (integral equations) via the theory of FEM. To make it general, the library must be related with only mathematical entities and not depend on any specific physical problems.

Changes from OGS5

FemLib in OGS5 already provides adequate functionality required for FEM. Main changes of the library in OGS6 are focused on the code structure for improving its extendibility as below

Modularization of FemLib
- Be independent from particular physics
- FE class does not include local assembly. Instead, local assembly calls FE class.
FE class as composition
- Be flexible for extension
- Components are shape function, integration method, extrapolation method, mapping, etc.

Scope

As today’s FEM theory has various kinds of its deviations, we define the scopes of this library as below:

The library provides discretization tools based on the classical Galerkin FEM with C0 elements. C1 elements are currently not supported. Discretization tools mean functions for interpolation, extrapolation and integration.
The library supports multi-dimensional elements (1-3D). Supported shapes are line, quad, triangle, hex, tetrahedral, pyramid and prismatic. Axisymmetric and mixed-dimension problems are also supported.
TODO: Adaptive meshin
The library does not include other kinds of numerical methods such as time stepping method, nonlinear solution method.

Roles

Approximation of continuous or discontinuous variable distributions by discrete values and basis functions.
Numerical integration of discretized terms over a mesh element ant along its part of boundary for, e.g. local assembly and calculation of Neumann conditions.
- Volume integration of a Laplace term:
- Boundary integration of a Neumann condition:
Conversion of one kind of discrete values to another kind, i.e. interpolation, extrapolation. For example, extrapolation of integration point values to nodal values.

Functionality

Finite element types
- C0 isoparametric elements (Polynomial order: Linear, Quadratic)
  - LINE2, LINE3, QUAD4, QUAD9, HEX8, HEX20, TRI3, TRI6, TET4,TET10, PRISM6, PRISM15,PYRAMID5, PYRAMID13
- Analytical integration elements (valid only if material properties are element constant)
  - TRI3CONST, TET4CONST
- TODO: Equi-dimensional interface elements
Geometry
- Axisymmetry (i.e. cylinder coordinates)
- Multi-dimensional elements (i.e. 2.5D elements in 3D)

Syntax

Users do not explicitly write equations for axisymmetric case. This is handled internally in FemLib.

Finite element types

Type	Dim.	Mesh element	Nr. of DoFs	Order	Continuity	Mapping	Integration	Extrapolation
LINE2	1	Line2	2	1	C0	Isoparametric	Gauss(ngp=2)	Linear
	>1					Isoparametric & Local coord.
	Axis					Isoparametric & Cylinder coord.
LINE3	1	Line3	3	2	C0	Isoparametric	Gauss(2)	Linear
	>1					Isoparametric & Local coord.
	Axis					Isoparametric & Cylinder coord.
TRI3	2	Tri3	3	1	C0	Isoparametric	Gauss(3)	Linear
	>2					Isoparametric & Local coord.
	Axis					Isoparametric & Cylinder coord.
TRI3CONST	2	Tri3	3	1	C0	-	Analytical
TRI6	2	Tri6	6	2	C0	Isoparametric	Gauss(3)	Linear
	>2					Isoparametric & Local coord.
	Axis					Isoparametric & Cylinder coord.
QUAD4	2	Quad4	4	1	C0	Isoparametric	Gauss	Linear
	>2					Isoparametric & Local coord.
	Axis					Isoparametric & Cylinder coord.
QUAD8	2	Quad8	8	2	C0	Isoparametric	Gauss	Linear
	>2					Isoparametric & Local coord.
	Axis					Isoparametric & Cylinder coord.
QUAD9	2	Quad9	9	2	C0	Isoparametric	Gauss	Linear
	>2					Isoparametric & Local coord.
	Axis					Isoparametric & Cylinder coord.
HEX8	3	Hex8	8	1	C0	Isoparametric	Gauss	Linear
HEX20	3	Hex20	20	2	C0	Isoparametric	Gauss	Linear
HEX27	3	Hex27	27	2	C0	Isoparametric	Gauss	Linear
TETRA4	3	Tetra4	4	1	C0	Isoparametric	Gauss(5)	Linear
TETRA10	3	Tetra10	10	2	C0	Isoparametric	Gauss(5)	Linear
PRISM6	3	Prism6	6	1	C0	Isoparametric	Gauss(6)	Average
PRISM15	3	Prism15	15	2	C0	Isoparametric	Gauss(6)	Average
PYRAMID5	3	Pyramid5	5	1	C0	Isoparametric	Gauss(5)	Average
PYRAMID13	3	Pyramid13	13	1	C0	Isoparametric	Gauss(8)	Average
EIE_QUAD4	2	Quad4	4	1	C0	Isoparametric & Local coord.	Gauss
EIE_QUAD6	2	Quad6	6	2	C0	Isoparametric & Local coord.	Gauss
EIE_TRI3	2	Tri3	3	1	C0	Isoparametric & Local coord.	Gauss
EIE_TRI5	2	Tri5	5	2	C0	Isoparametric & Local coord.	Gauss
EIE_HEX8	3	Hex8	8	1	C0	Isoparametric & Local coord.	Gauss
EIE_HEX16	3	Hex16	16	2	C0	Isoparametric & Local coord.	Gauss
EIE_PRISM6	3	Prism6	6	1	C0	Isoparametric & Local coord.	Gauss
EIE_PRISM12	3	Prism12	12	2	C0	Isoparametric & Local coord.	Gauss
EIE_TETRA4	3	Tetra4	4	1	C0	Isoparametric & Local coord.	Gauss
EIE_TETRA9	3	Tetra9	9	2	C0	Isoparametric & Local coord.	Gauss
EIE_PYRAMID5	3	Pyramid5	5	1	C0	Isoparametric & Local coord.	Gauss
EIE_PYRAMID11	3	Pyramid11	11	2	C0	Isoparametric & Local coord.	Gauss

Use case

TODO: With this component, users should be able to do the followings,

Users can discretize any integration terms over the given element with the given finite element types.
Users can include constrains (Dirichlet, Neumann, Robin B.C.) to discrete equations.
Users can interpolate values at the given points with nodal values.
Users can extrapolate values at nodes with integration point values. Scenarios

Provide feedback

Saved searches

Use saved searches to filter your results more quickly