1 
jgs 
110 
% $Id$ 
2 
gross 
568 

3 


The \LinearPDE class is used to define a general linear, steady, second order PDE 
4 


for an unknown function $u$ on a given $\Omega$ defined through a \Domain object. 
5 


In the following $\Gamma$ denotes the boundary of the domain $\Omega$. $n$ denotes 
6 


the outer normal field on $\Gamma$. 
7 



8 


For a single PDE with a solution with a single component the linear PDE is defined in the 
9 


following form: 
10 


\begin{equation}\label{LINEARPDE.SINGLE.1} 
11 


(A\hackscore{jl} u\hackscore{,l}){,j}+(B\hackscore{j} u)\hackscore{,j}+C\hackscore{l} u\hackscore{,l}+D u =X\hackscore{j,j}+Y \; . 
12 


\end{equation} 
13 


$u_{,j}$ denotes the derivative of $u$ with respect to the $j$th spatial direction. Einstein's summation convention, ie. summation over indexes appearing twice in a term of a sum is performed, is used. 
14 


The coefficients $A$, $B$, $C$, $D$, $X$ and $Y$ have to be specified through \Data objects in the 
15 


\Function on the PDE or objects that can be converted into such \Data objects. 
16 


$A$ is a \RankTwo, $B$, $C$ and $X$ are \RankOne and $D$ and $Y$ are scalar. 
17 


The following natural 
18 


boundary conditions are considered \index{boundary condition!natural} on $\Gamma$: 
19 


\begin{equation}\label{LINEARPDE.SINGLE.2} 
20 


n\hackscore{j}(A\hackscore{jl} u\hackscore{,l}+B\hackscore{j} u)+d u=n\hackscore{j}X\hackscore{j} + y \;. 
21 


\end{equation} 
22 


Notice that the coefficients $A$, $B$ and $X$ are defined in the PDE. The coefficients $d$ and $y$ are 
23 


each a \Scalar in the \FunctionOnBoundary. Constraints \index{constraint} for the solution prescribing the value of the 
24 


solution at certain locations in the domain. They have the form 
25 


\begin{equation}\label{LINEARPDE.SINGLE.3} 
26 


u=r \mbox{ where } q>0 
27 


\end{equation} 
28 


$r$ and $q$ are each \Scalar where $q$ is the characteristic function 
29 


\index{characteristic function} defining where the constraint is applied. 
30 


The constraints defined by \eqn{LINEARPDE.SINGLE.3} override any other condition set by \eqn{LINEARPDE.SINGLE.1} 
31 


or \eqn{LINEARPDE.SINGLE.2}. The PDE is symmetrical \index{symmetrical} if 
32 


\begin{equation}\label{LINEARPDE.SINGLE.4} 
33 


A\hackscore{jl}=A\hackscore{lj} \mbox{ and } B\hackscore{j}=C\hackscore{j} 
34 


\end{equation} 
35 


For a system of PDEs and a solution with several components the PDE has the form 
36 


\begin{equation}\label{LINEARPDE.SYSTEM.1} 
37 


(A\hackscore{ijkl} u\hackscore{k,l}){,j}+(B\hackscore{ijk} u_k)\hackscore{,j}+C\hackscore{ikl} u\hackscore{k,l}+D\hackscore{ik} u_k =X\hackscore{ij,j}+Y\hackscore{i} \; . 
38 


\end{equation} 
39 


$A$ is a \RankFour, $B$ and $C$ are each a \RankThree, $D$ and $X$ are each a \RankTwo and $Y$ is a \RankOne. 
40 


The natural boundary conditions \index{boundary condition!natural} take the form: 
41 


\begin{equation}\label{LINEARPDE.SYSTEM.2} 
42 


n\hackscore{j}(A\hackscore{ijkl} u\hackscore{k,l}){,j}+(B\hackscore{ijk} u_k)+d\hackscore{ik} u_k=n\hackscore{j}X\hackscore{ij}+y\hackscore{i} \;. 
43 


\end{equation} 
44 


The coefficient $d$ is a \RankTwo and $y$ is a 
45 


\RankOne both in the \FunctionOnBoundary. Constraints \index{constraint} take the form 
46 


\begin{equation}\label{LINEARPDE.SYSTEM.3} 
47 


u\hackscore{i}=r\hackscore{i} \mbox{ where } q\hackscore{i}>0 
48 


\end{equation} 
49 


$r$ and $q$ are each \RankOne. Notice that at some locations not necessarily all components must 
50 


have a constraint. The system of PDEs is symmetrical \index{symmetrical} if 
51 


\begin{eqnarray}\label{LINEARPDE.SYSTEM.4} 
52 


A\hackscore{ijkl}=A\hackscore{klij} \\ 
53 


B\hackscore{ijk}=C\hackscore{kij} \\ 
54 


D\hackscore{ik}=D\hackscore{ki} \\ 
55 


d\hackscore{ik}=d\hackscore{ki} \ 
56 


\end{eqnarray} 
57 


\LinearPDE also supports solution discontinuities \index{discontinuity} over contact region $\Gamma^{contact}$ 
58 


in the domain $\Omega$. To specify the conditions across the discontinuity we are using the 
59 


generalised flux $J$ which is in the case of a systems of PDEs and several components of the solution 
60 


defined as 
61 


\begin{equation}\label{LINEARPDE.SYSTEM.5} 
62 


J\hackscore{ij}=A\hackscore{ijkl}u\hackscore{k,l}+B\hackscore{ijk}u\hackscore{k}X\hackscore{ij} 
63 


\end{equation} 
64 


For the case of single solution component and single PDE $J$ is defined 
65 


\begin{equation}\label{LINEARPDE.SINGLE.5} 
66 


J\hackscore{j}=A\hackscore{jl}u\hackscore{,l}+B\hackscore{j}u\hackscore{k}X\hackscore{j} 
67 


\end{equation} 
68 


In the context of discontinuities \index{discontinuity} $n$ denotes the normal on the 
69 


discontinuity pointing from side 0 towards side 1. For a system of PDEs 
70 


the contact condition takes the form 
71 


\begin{equation}\label{LINEARPDE.SYSTEM.6} 
72 


n\hackscore{j} J^{0}\hackscore{ij}=n\hackscore{j} J^{1}\hackscore{ij}=y^{contact}\hackscore{i}  d^{contact}\hackscore{ik} [u]\hackscore{k} \; . 
73 


\end{equation} 
74 


where $J^{0}$ and $J^{1}$ are the fluxes on side $0$ and side $1$ of the 
75 


discontinuity $\Gamma^{contact}$, respectively. $[u]$, which is the difference 
76 


of the solution at side 1 and at side 0, denotes the jump of $u$ across $\Gamma^{contact}$. 
77 


The coefficient $d^{contact}$ is a \RankTwo and $y^{contact}$ is a 
78 


\RankOne both in the \FunctionOnContactZero or \FunctionOnContactOne. 
79 


In case of a single PDE and a single component solution the contact condition takes the form 
80 


\begin{equation}\label{LINEARPDE.SINGLE.6} 
81 


n\hackscore{j} J^{0}\hackscore{j}=n\hackscore{j} J^{1}\hackscore{j}=y^{contact}  d^{contact}[u] 
82 


\end{equation} 
83 


In this case the the coefficient $d^{contact}$ and $y^{contact}$ are eaach \Scalar 
84 


both in the \FunctionOnContactZero or \FunctionOnContactOne. 
85 


====================== 
86 



87 



88 


We have used a special case of the \LinearPDE class, namely the 
89 


\Poisson class already in \Chap{FirstSteps}. 
90 


Here we will write our own specialized subclass of the \LinearPDE to define the Helmholtz equation 
91 


and use the \method{getSolution} method of parent class to actually solve the problem. 
92 



93 


The form of a single PDE that can be handled by the \LinearPDE class is 
94 


\begin{equation}\label{EQU.FEM.1} 
95 


(A\hackscore{jl} u\hackscore{,l})\hackscore{,j}+D u =Y \; . 
96 


\end{equation} 
97 


We show here the terms which are relevant for the Helmholtz problem. 
98 


The general form and systems is discussed in \Sec{SEC LinearPDE}. 
99 


$A$, $D$ and $Y$ are the known coeffecients of the PDE. \index{partial differential equation!coefficients} 
100 


Notice that $A$ is a matrix or tensor of order 2 and $D$ and $Y$ are scalar. 
101 


They may be constant or may depend on their 
102 


location in the domain but must not depend on the unknown solution $u$. 
103 


The following natural boundary conditions \index{boundary condition!natural} that 
104 


are used in the \LinearPDE class have the form 
105 


\begin{equation}\label{EQU.FEM.2} 
106 


n\hackscore{j}A\hackscore{jl} u\hackscore{,l}+du=y \;. 
107 


\end{equation} 
108 


where, as usual, $n$ denotes the outer normal field on the surface of the domain. Notice that 
109 


the coefficient $A$ is already used in the PDE in \eqn{EQU.FEM.1}. $d$ and $y$ are given scalar coefficients. 
110 



111 


By inspecting the Helmholtz equation \index{Helmholtz equation} 
112 


we can easily assign values to the coefficients in the 
113 


general PDE of the \LinearPDE class: 
114 


\begin{equation}\label{DIFFUSION HELM EQ 3} 
115 


\begin{array}{llllll} 
116 


A\hackscore{ij}=\kappa \delta\hackscore{ij} & D=\omega & Y=f \\ 
117 


d=\eta & y= g & \\ 
118 


\end{array} 
119 


\end{equation} 
120 


$\delta\hackscore{ij}$ is the Kronecker symbol \index{Kronecker symbol} defined by $\delta\hackscore{ij}=1$ for 
121 


$i=j$ and $0$ otherwise. 
122 



123 


We want to implement a 
124 


new class which we will call \class{Helmholtz} that provides the same methods as the \LinearPDE class but 
125 


is described using the coefficients $\kappa$, $\omega$, $f$, $\eta$, 
126 


$g$ rather than the general form given by \eqn{EQU.FEM.1}. 
127 


Python's mechanism of subclasses allows us to do this in a very simple way. 
128 


The \Poisson class of the \linearPDEs module, 
129 


which we have already used in \Chap{FirstSteps}, is in fact a subclass of the more general 
130 


\LinearPDE class. That means that all methods (such as the \method{getSolution}) 
131 


from the parent class \LinearPDE are available for any \Poisson object. However, new 
132 


methods can be added and methods of the parent class can be redefined. In fact, 
133 


the \Poisson class redefines the \method{setValue} of the \LinearPDE class which is called to assign 
134 


values to the coefficients of the PDE. This is exactly what we will do when we define 
135 


our new \class{Helmholtz} class: 
136 


\begin{python} 
137 


from esys.linearPDEs import LinearPDE 
138 


import numarray 
139 


class Helmholtz(LinearPDE): 
140 


def setValue(self,kappa=0,omega=1,f=0,eta=0,g=0) 
141 


ndim=self.getDim() 
142 


kronecker=numarray.identity(ndim) 
143 


self.setValue(A=kappa*kronecker,D=omega,Y=f,d=eta,y=g) 
144 


\end{python} 
145 


\code{class Helmholtz(linearPDE)} declares the new \class{Helmholtz} class as a subclass 
146 


of \LinearPDE which we have imported in the first line of the script. 
147 


We add the method \method{setValue} to the class which overwrites the 
148 


\method{setValue} method of the \LinearPDE class. The new method which has the 
149 


parameters of the Helmholtz \eqn{DIFFUSION HELM EQ 1} as arguments 
150 


maps the parameters of the coefficients of the general PDE defined 
151 


in \eqn{EQU.FEM.1}. We are actually using the \method{_LinearPDE__setValue} of 
152 


the \LinearPDE class. 
153 


The coefficient \var{A} involves the Kronecker symbol. We use the 
154 


\numarray function \function{identity} which returns a square matrix with ones on the 
155 


main diagonal and zeros off the main diagonal. The argument of \function{identity} gives the order of the matrix. 
156 


The \method{getDim} of the \LinearPDE class object \var{self} to get the spatial dimensions of the domain of the 
157 


PDE. As we will make use of the \class{Helmholtz} class several times, it is convenient to 
158 


put its definition into a file which we name \file{mytools.py} available in the \ExampleDirectory. 
159 


You can use your favourite editor to create and edit the file. 
160 



161 


An object of the \class{Helmholtz} class is created through the statments: 
162 


\begin{python} 
163 


from mytools import Helmholtz 
164 


mypde = Helmholtz(mydomain) 
165 


mypde.setValue(kappa=10.,omega=0.1,f=12) 
166 


u = mypde.getSolution() 
167 


\end{python} 
168 


In the first statement we import all definition from the \file{mytools.py} \index{scripts!\file{mytools.py}}. Make sure 
169 


that \file{mytools.py} is in the directory from where you started Python. 
170 


\var{mydomain} is the \Domain of the PDE which we have undefined here. In the third statment values are 
171 


assigned to the PDE parameters. As no values for arguments \var{eta} and \var{g} are 
172 


specified, the default values $0$ are used. \footnote{It would be better to use the default value 
173 


\var{escript.Data()} rather then $0$ as then the coefficient would be defined as being not present and 
174 


would not be processed when the PDE is evaluated}. In the fourth statement the solution of the 
175 


PDE is returned. 
176 



177 


To test our \class{Helmholtz} class on a rectangular domain 
178 


of length $l\hackscore{0}=5$ and height $l\hackscore{1}=1$, we choose a simple test solution. Actually, we 
179 


we take $u=x\hackscore{0}$ and then calculate the right hand side terms $f$ and $g$ such that 
180 


the test solution becomes the solution of the problem. If we assume $\kappa$ as being constant, 
181 


an easy calculation shows that we have to choose $f=\omega \cdot x\hackscore{0}$. On the boundary we get 
182 


$\kappa n\hackscore{i} u\hackscore{,i}=\kappa n\hackscore{0}$. 
183 


So we have to set $g=\kappa n\hackscore{0}+\eta x\hackscore{0}$. The following script \file{helmholtztest.py} 
184 


\index{scripts!\file{helmholtztest.py}} which is available in the \ExampleDirectory 
185 


implements this test problem using the \finley PDE solver: 
186 


\begin{python} 
187 


from mytools import Helmholtz 
188 


from esys.escript import Lsup 
189 


from esys.finley import Rectangle 
190 


#... set some parameters ... 
191 


kappa=1. 
192 


omega=0.1 
193 


eta=10. 
194 


#... generate domain ... 
195 


mydomain = Rectangle(l0=5.,l1=1.,n0=50, n1=10) 
196 


#... open PDE and set coefficients ... 
197 


mypde=Helmholtz(mydomain) 
198 


n=mydomain.getNormal() 
199 


x=mydomain.getX() 
200 


mypde.setValue(kappa,omega,omega*x[0],eta,kappa*n[0]+eta*x[0]) 
201 


#... calculate error of the PDE solution ... 
202 


u=mypde.getSolution() 
203 


print "error is ",Lsup(ux[0]) 
204 


\end{python} 
205 


The script is similar to the script \file{mypoisson.py} dicussed in \Chap{FirstSteps}. 
206 


\code{mydomain.getNormal()} returns the outer normal field on the surface of the domain. The function \function{Lsup} 
207 


is imported by the \code{from esys.escript import Lsup} statement and returns the maximum absulute value of its argument. 
208 


The error shown by the print statement should be in the order of $10^{7}$. As piecewise bilinear interpolation is 
209 


used to approximate the solution and our solution is a linear function of the spatial coordinates one might 
210 


expect that the error would be zero or in the order of machine precision (typically $\approx 10^{15}$). 
211 


However most PDE packages use an iterative solver which is terminated 
212 


when a given tolerance has been reached. The default tolerance is $10^{8}$. This value can be altered by using the 
213 


\method{setTolerance} of the \LinearPDE class. 
214 



215 


\subsection{The Transition Problem} 
216 


\label{DIFFUSION TRANS SEC} 
217 


Now we are ready to solve the original time dependent problem. The main 
218 


part of the script is the loop over time $t$ which takes the following form: 
219 


\begin{python} 
220 


t=0 
221 


T=Tref 
222 


mypde=Helmholtz(mydomain) 
223 


while t<t_end: 
224 


mypde.setValue(kappa,rhocp/h,q+rhocp/h*T,eta,eta*Tref) 
225 


T=mypde.getSolution() 
226 


t+=h 
227 


\end{python} 
228 


\var{kappa}, \var{rhocp}, \var{eta} and \var{Tref} are input parameters of the model. \var{q} is the heat source 
229 


in the domain and \var{h} is the time step size. Notice that the \class{Hemholtz} class object \var{mypde} 
230 


is created before the loop over time is entered while in each time step only the coefficients 
231 


are reset in each time step. This way some information about the representation of the PDE can be reused 
232 


\footnote{The efficience can be improved further by setting the coefficients in the operator 
233 


\var{kappa}, \var{omega} and \var{eta} before entering the \code{while}loop and only updating the coefficients 
234 


in the right hand side \var{f} and \var{g}. This needs a more careful implementation of the \method{setValue} 
235 


method but gives the advantage that the \LinearPDE class can save rebuilding the PDE operator.}. The variable \var{T} 
236 


holds the current temperature. It is used to calculate the right hand side coefficient \var{f} in the 
237 


Helmholtz equation in \eqn{DIFFUSION HELM EQ 1}. The statement \code{T=mypde.getSolution()} overwrites \var{T} with the 
238 


temperature of the new time step $\var{t}+\var{h}$. To get this iterative process going we need to specify the 
239 


initial temperature distribution, which equal to $T\hackscore{ref}$. 
240 



241 


The heat source \var{q} which is defined in \eqn{DIFFUSION TEMP EQ 1b} is \var{qc} 
242 


in an area defined as a circle of radius \var{r} and center \var{xc} and zero outside this circle. 
243 


\var{q0} is a fixed constant. The following script defines \var{q} as desired: 
244 


\begin{python} 
245 


from esys.escript import length 
246 


xc=[0.02,0.002] 
247 


r=0.001 
248 


x=mydomain.getX() 
249 


q=q0*(length(xxc)r).whereNegative() 
250 


\end{python} 
251 


\var{x} is a \Data class object of 
252 


the \escript module defining locations in the \Domain \var{mydomain}. 
253 


The \function{length()} imported from the \escript module returns the 
254 


Euclidean norm: 
255 


\begin{equation}\label{DIFFUSION HELM EQ 3aba} 
256 


\y\=\sqrt{ 
257 


y\hackscore{i} 
258 


y\hackscore{i} 
259 


} = \function{esys.escript.length}(y) 
260 


\end{equation} 
261 


So \code{length(xxc)} calculates the distances 
262 


of the location \var{x} to the center of the circle \var{xc} where the heat source is acting. 
263 


Note that the coordinates of \var{xc} are defined as a list of floating point numbers. It is independently 
264 


converted into a \Data class object before being subtracted from \var{x}. The method \method{whereNegative} of 
265 


a \Data class object, in this case the result of the expression 
266 


\code{length(xxc)r}, returns a \Data class which is equal to one where the object is negative and 
267 


zero elsewhere. After multiplication with \var{qc} we get a function with the desired property. 
268 



269 


Now we can put the components together to create the script \file{diffusion.py} which is available in the \ExampleDirectory: 
270 


\index{scripts!\file{diffusion.py}}: 
271 


\begin{python} 
272 


from mytools import Helmholtz 
273 


from esys.escript import Lsup 
274 


from esys.finley import Rectangle 
275 


#... set some parameters ... 
276 


xc=[0.02,0.002] 
277 


r=0.001 
278 


qc=50.e6 
279 


Tref=0. 
280 


rhocp=2.6e6 
281 


eta=75. 
282 


kappa=240. 
283 


tend=5. 
284 


# ... time, time step size and counter ... 
285 


t=0 
286 


h=0.1 
287 


i=0 
288 


#... generate domain ... 
289 


mydomain = Rectangle(l0=0.05,l1=0.01,n0=250, n1=50) 
290 


#... open PDE ... 
291 


mypde=Helmholtz(mydomain) 
292 


# ... set heat source: .... 
293 


x=mydomain.getX() 
294 


q=qc*(length(xxc)r).whereNegative() 
295 


# ... set initial temperature .... 
296 


T=Tref 
297 


# ... start iteration: 
298 


while t<tend: 
299 


i+=1 
300 


t+=h 
301 


print "time step :",t 
302 


mypde.setValue(kappa=kappa,omega=rhocp/h,f=q+rhocp/h*T,eta=eta,g=eta*Tref) 
303 


T=mypde.getSolution() 
304 


T.saveDX("T%d.dx"%i) 
305 


\end{python} 
306 


The script will create the files \file{T.1.dx}, 
307 


\file{T.2.dx}, $\ldots$, \file{T.50.dx} in the directory where the script has been started. The files give the 
308 


temperature distributions at time steps $1$, $2$, $\ldots$, $50$ in the \OpenDX file format. 
309 



310 


\begin{figure} 
311 


\centerline{\includegraphics[width=\figwidth]{DiffusionRes1}} 
312 


\centerline{\includegraphics[width=\figwidth]{DiffusionRes16}} 
313 


\centerline{\includegraphics[width=\figwidth]{DiffusionRes32}} 
314 


\centerline{\includegraphics[width=\figwidth]{DiffusionRes48}} 
315 


\caption{Results of the Temperture Diffusion Problem for Time Steps $1$ $16$, $32$ and $48$.} 
316 


\label{DIFFUSION FIG 2} 
317 


\end{figure} 
318 



319 


An easy way to visualize the results is the command 
320 


\begin{verbatim} 
321 


dx edit diffusion.net & 
322 


\end{verbatim} 
323 


where \file{diffusion.net} is an \OpenDX script available in the \ExampleDirectory. 
324 


Use the \texttt{Sequencer} to move forward and and backwards in time. 
325 


\fig{DIFFUSION FIG 2} shows the result for some selected time steps. 
326 


==== 
327 
jgs 
121 
\section{Bending Beam under Uniform Load} 
328 
jgs 
110 
\label{BEAM CHAP} 
329 


\sectionauthor{Jannine Eisenmann}{} 
330 



331 


Given is a twodimension bending beam which is fixed in all directions 
332 


at the left end and free at the other, see \fig{BEAM FIG 1}. Furthermore the beam is loaded 
333 


with a uniform load $p$. 
334 



335 


\begin{figure} 
336 


% \centerline{\includegraphics[width=\figwidth]{DiffusionRes1}} 
337 


\caption{Loaded Beam.} 
338 


\label{BEAM FIG 1} 
339 


\end{figure} 
340 



341 



342 



343 


For emphasizing the displacement this picture is drawn (uebertrieben), 
344 


cause since we use the linear theory otherwise no displacements would 
345 


be visible. 
346 


There are two ways of solving this problem: on the one hand one can 
347 


use the differential equation for the deformed neutral fibre of the 
348 


beam. This classical differential equation is based on several simplifying 
349 


assumptions concerning the statics and kinematics of the problem. 
350 


However the results are known to be highly accurate at least for slender 
351 


beams with length to hight ratios $> 10$. Alternatively, in connection 
352 


with finite element based differential equation toolkits one may simply 
353 


consider the beam as a special case of a 2D or 3D elastic continuum 
354 


problem and solve the stress equilibrium equations combined with Hooke's 
355 


law for the specific boundary conditions of a beam. Both cases assume 
356 


isotropic and linear elastic material properties. 
357 



358 


The beam equation is easily solved analytically. The analytical solutions 
359 


can be used for benchmarkung finite element solutions. In section 
360 


1.2 we formluate a finite element code for general isotropic elasticity 
361 


problems including thin and deep beams under arbitrary loading conditiond 
362 


in 2D or 3D. 
363 



364 



365 


\section{2dimensional} 
366 


As the stress equilibrium equation is a partial differential equation 
367 


(PDE), we choose to use Finley to solve it, since Finley is a finite 
368 


element kernel library, that has been incorporated as a differential 
369 


equation solver into the python based numerical toolkit called escript. 
370 


We divided the beam into ten square elements of the size 1x1. Each 
371 


element consists of 8 nodes, which leads to a quadratic interpolation 
372 


of the model point displacements \\ 
373 



374 


The key ingredients is \textbf{Hooks Law}. We use Hooks Law because 
375 


we are dealing with \textbf{linear elastic material} \textbf{behaviour}. 
376 


We have \\ 
377 



378 



379 


$\sigma_{ik}=2G\left(\varepsilon_{ik}+\frac{\nu}{12\nu}\cdot e\cdot\delta_{ik}\right)$\hfill{}(1)\\ 
380 


where the engineering strain$\varepsilon_{ik}$is defined as: 
381 



382 


$\varepsilon_{ik}=\frac{1}{2}\cdot\left(u_{k,i}+u_{i,k}\right)$\hfill{}(2)\\ 
383 



384 



385 


with 
386 



387 


\begin{enumerate} 
388 


\item e= Volume strain = $\varepsilon_{kk}$ 
389 


\item $\delta_{ik}$= Kronecker symbol 
390 


\end{enumerate} 
391 


Inserting equation (2) in (1) (and with further mathematical conversions) 
392 


leads to the following partial differential equation :\\ 
393 



394 



395 


$\sigma_{ij}=\left[\mu\left(\delta_{ik}\delta_{jl}+\delta_{il}\delta_{jk}\right)+\lambda\left(\delta_{ij}\delta_{kl}\right)\right]u_{k,l}$\\ 
396 



397 



398 


For tension equilibrium we require:\\ 
399 



400 



401 


$\sigma_{ij,j}=0$\\ 
402 



403 



404 


which leads to the following expression:\\ 
405 



406 



407 


\[ 
408 


\left(\left[\mu\left(\delta_{ik}\delta_{jl}+\delta_{il}\delta_{jk}\right)+\lambda\left(\delta_{ij}\delta_{kl}\right)\right]u_{k,l}\right)_{,j}=0\] 
409 



410 



411 


with the natural boundary condition: 
412 



413 


\[ 
414 


n_{j}\sigma_{ij}=p_{i}\] 
415 


\\ 
416 


$p_{i}$ representing a uniform load on top of the beam. 
417 



418 


A Dirichlet Boundary condition is assumed on the left end of the beam 
419 


for which no displacements can occure.\\ 
420 


\\ 
421 


\includegraphics[% 
422 


width=0.60\linewidth,bb = 0 0 200 100, draft, type=eps]{/home/jeannine/sandbox/report/draws/dir_cond_beam.eps}\\ 
423 


This is described in the code with the setting a mask for the left 
424 


end and setting values to that mask: 
425 



426 


\begin{python} 
427 


q = xNodes{[}0{]}.whereZero(){*}{[}1.0,1.0{]} 
428 



429 


r = Vector({[}0.0, 0.0{]}, where = nodes) 
430 


\end{python} 
431 


The Finley template PDE reads:\\ 
432 



433 



434 


\[ 
435 


(A_{ijkl}u_{k,l})_{,j}(B_{ijk}u_{k})_{,j}+C_{ikl}u_{k,l}+D_{ik}u_{k}=X_{ij,j}+Y_{i}\] 
436 


\\ 
437 


with the natural boundary condition: 
438 



439 


\[ 
440 


n_{j}(A_{ijkl}u_{k,l}+B_{ijkl}u_{k})+d_{ik}u_{k}=n_{j}X_{ij}+y_{i}on\Gamma_{i}^{D}\] 
441 



442 



443 


Yields by comparing the coefficients : 
444 



445 


\begin{enumerate} 
446 


\item $A_{ijkl}$= $\left[\mu\left(\delta_{ik}\delta_{ij}+\delta_{jl}\delta_{il}\right)+\lambda\left(\delta_{ij}\delta_{kl}\right)\right]$ 
447 


\item $y_{i}$= $p_{i}$ 
448 


\item $u_{k}$= displacement $u$ 
449 


\end{enumerate} 
450 


$B_{ijk,}=C_{ikl}=D_{ik}=X_{ij}=Y_{i}=d_{ik}=0$\\ 
451 



452 



453 


Where 0 in the last line is taken as a scalar, vector or tensor, depending 
454 


on what the belonging coefficient is. 
455 



456 


These equations are the base for the \textbf{Finley Script}: 
457 



458 


\begin{python} 
459 


from ESyS import {*} 
460 


import Finley 
461 



462 



463 



464 


\#mu lamda 
465 



466 


def mu (E, nu): \#= shear modul G 
467 



468 


return E/(2{*}(1+nu)) 
469 



470 


def lamda (E, nu): 
471 



472 


return (nu{*}E)/((12{*}nu){*}(1+nu)) 
473 



474 



475 



476 


def main() 
477 



478 


\#material, beam PROPERTIES 
479 



480 


L = 10.0 \#length of beam {[}m{]} 
481 



482 


h = 1 \#height of beam {[}m{]} 
483 



484 


p = 1 \#outer uniform load {[}kN/m{]} 
485 



486 


E0 = 210000 \#Young's modulus {[}kN/m\textasciicircum{}2{]} 
487 



488 


nu = 0.4 \#Poisson ratio {[}{]} 
489 



490 



491 



492 


print \char`\"{}L=\char`\"{}, L 
493 



494 


print \char`\"{}h=\char`\"{}, h 
495 



496 


print \char`\"{}p=\char`\"{}, p 
497 



498 


print \char`\"{}E=\char`\"{}, E0 
499 



500 


print \char`\"{}nu=Poisson =\char`\"{}, nu 
501 



502 


print \char`\"{}mu=\char`\"{}, mu (E0,nu) 
503 



504 


print \char`\"{}lamda=\char`\"{}, lamda (E0,nu) 
505 



506 



507 



508 


\#SET MESH for FE 
509 



510 


mesh= Finley.Rectangle(n0=10 ,n1=1 ,order=2, l0=L, l1=h) 
511 



512 


nodes = mesh.Nodes() 
513 



514 


xNodes = nodes.getX() 
515 



516 


elements = mesh.Elements() 
517 



518 


faceElements = mesh.FaceElements() 
519 



520 


xFaceElements = faceElements.getX() 
521 



522 



523 



524 


\#DISPLACEMENT boundary 
525 



526 


q = xNodes{[}0{]}.whereZero(){*}{[}1.,1.0{]} \#setting the mask for r 
527 



528 


r = Vector({[}0.0, 0.0{]}, where = nodes) \#fixed end 
529 



530 



531 



532 


\#STRESS boundary 
533 



534 


ymask = xFaceElements{[}1{]}.whereEqualTo(h) 
535 



536 


y = Vector({[}0, p{]}, where = faceElements) 
537 



538 


y = y{*}ymask 
539 



540 



541 



542 


\#Finley coeff. 
543 



544 


A = Tensor4(0, where = elements) 
545 



546 


for i in range (2) : 
547 



548 


for j in range (2) : 
549 



550 


A{[}i,i,j,j{]}+= lamda (E0,nu) 
551 



552 


A{[}j,i,j,i{]}+= mu (E0,nu) 
553 



554 


A{[}j,i,i,j{]}+= mu (E0,nu) 
555 



556 



557 



558 


M,b = mesh.assemble(A=A, B=B, q=q, 
559 



560 


y=y,r=r,type=CSR,num\_equations=2) 
561 



562 


u= M.iterative(b, tolerance=1e8,iter\_max=50000, 
563 



564 


iterative\_method=PCG) 
565 



566 


print \char`\"{}u{[}0{]}=\char`\"{},u{[}0{]} 
567 



568 


print \char`\"{}u{[}1{]}=\char`\"{},u{[}1{]} 
569 



570 


main() 
571 


\end{python} 
572 


The finer the mesh the more exact is the solution. E.g. a 20x2 mesh 
573 


is more exact than a 10x1 mesh. 
574 


