Finite Element formulation of mixed BVP of Variational Problem











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Suppose we are given the followin where $f$,$u$, $g$ are given functions:



$-Delta u = f$ in $Omega$



$u=u_o$ on $Gamma_1$



$frac{du}{dn}=g$ on $Gamma_2$



So in order for me to form the variational problem which is the first step, I did the following.



Assume $u_o$ is sufficiently smooth on $hat{Gamma}$ then, $hat{u}=u-u_o$



This results in:



$-Delta hat{u}= f$ in $hat{Omega}$



$hat{u}=0$ on $hat{Gamma_1}$



$frac{dhat{u}}{dn}=g-frac{du_o}{dn}$



If I let $V$={$v in H^1(Omega): v|_{Gamma_1} = 0$}



Then by applying my test function v and using Green's Formula, I can show that the new problem I've created is similar to the original problem and it results in:



$int_{Omega} nabla u nabla vdx$ = $int_{Omega}fvdx+int_{Gamma_2}gv ds $



where the bilinear case is $a<u,v> = int_{Omega} nabla u nabla vdx$



the linear case is $L(v) = int_{Omega}fvdx+int_{Gamma_2}gv ds $



So now that I have gotten the variational problem finished I need to implement some finite element method.



So this would mean I need to find a basis function which I would pick a triangulation in some smaller subspace $V_h=${$v_h$ is continous, linear.},



$phi_j(x)= 1$ if $i=j$ and $0$ if $ineq j$



So then,



$v_h=sum_{j=1}^{M} eta_j phi_j(x)$ are the linear combinations



Now essentially I need to get to some sort of formulation of the finite element method where I would have



$A zeta=b$ and then I could get some sort formulation of what the A matrix would look like. I know the A matrix will be symmetric and positive definite.
I know the following,



$A_{ij}= <phi_i' , phi_j'>$



$b=<f, phi_i>$



I'm stuck on the finite method part and I want to make sure I'm going about it the right way.










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    up vote
    0
    down vote

    favorite












    Suppose we are given the followin where $f$,$u$, $g$ are given functions:



    $-Delta u = f$ in $Omega$



    $u=u_o$ on $Gamma_1$



    $frac{du}{dn}=g$ on $Gamma_2$



    So in order for me to form the variational problem which is the first step, I did the following.



    Assume $u_o$ is sufficiently smooth on $hat{Gamma}$ then, $hat{u}=u-u_o$



    This results in:



    $-Delta hat{u}= f$ in $hat{Omega}$



    $hat{u}=0$ on $hat{Gamma_1}$



    $frac{dhat{u}}{dn}=g-frac{du_o}{dn}$



    If I let $V$={$v in H^1(Omega): v|_{Gamma_1} = 0$}



    Then by applying my test function v and using Green's Formula, I can show that the new problem I've created is similar to the original problem and it results in:



    $int_{Omega} nabla u nabla vdx$ = $int_{Omega}fvdx+int_{Gamma_2}gv ds $



    where the bilinear case is $a<u,v> = int_{Omega} nabla u nabla vdx$



    the linear case is $L(v) = int_{Omega}fvdx+int_{Gamma_2}gv ds $



    So now that I have gotten the variational problem finished I need to implement some finite element method.



    So this would mean I need to find a basis function which I would pick a triangulation in some smaller subspace $V_h=${$v_h$ is continous, linear.},



    $phi_j(x)= 1$ if $i=j$ and $0$ if $ineq j$



    So then,



    $v_h=sum_{j=1}^{M} eta_j phi_j(x)$ are the linear combinations



    Now essentially I need to get to some sort of formulation of the finite element method where I would have



    $A zeta=b$ and then I could get some sort formulation of what the A matrix would look like. I know the A matrix will be symmetric and positive definite.
    I know the following,



    $A_{ij}= <phi_i' , phi_j'>$



    $b=<f, phi_i>$



    I'm stuck on the finite method part and I want to make sure I'm going about it the right way.










    share|cite|improve this question
























      up vote
      0
      down vote

      favorite









      up vote
      0
      down vote

      favorite











      Suppose we are given the followin where $f$,$u$, $g$ are given functions:



      $-Delta u = f$ in $Omega$



      $u=u_o$ on $Gamma_1$



      $frac{du}{dn}=g$ on $Gamma_2$



      So in order for me to form the variational problem which is the first step, I did the following.



      Assume $u_o$ is sufficiently smooth on $hat{Gamma}$ then, $hat{u}=u-u_o$



      This results in:



      $-Delta hat{u}= f$ in $hat{Omega}$



      $hat{u}=0$ on $hat{Gamma_1}$



      $frac{dhat{u}}{dn}=g-frac{du_o}{dn}$



      If I let $V$={$v in H^1(Omega): v|_{Gamma_1} = 0$}



      Then by applying my test function v and using Green's Formula, I can show that the new problem I've created is similar to the original problem and it results in:



      $int_{Omega} nabla u nabla vdx$ = $int_{Omega}fvdx+int_{Gamma_2}gv ds $



      where the bilinear case is $a<u,v> = int_{Omega} nabla u nabla vdx$



      the linear case is $L(v) = int_{Omega}fvdx+int_{Gamma_2}gv ds $



      So now that I have gotten the variational problem finished I need to implement some finite element method.



      So this would mean I need to find a basis function which I would pick a triangulation in some smaller subspace $V_h=${$v_h$ is continous, linear.},



      $phi_j(x)= 1$ if $i=j$ and $0$ if $ineq j$



      So then,



      $v_h=sum_{j=1}^{M} eta_j phi_j(x)$ are the linear combinations



      Now essentially I need to get to some sort of formulation of the finite element method where I would have



      $A zeta=b$ and then I could get some sort formulation of what the A matrix would look like. I know the A matrix will be symmetric and positive definite.
      I know the following,



      $A_{ij}= <phi_i' , phi_j'>$



      $b=<f, phi_i>$



      I'm stuck on the finite method part and I want to make sure I'm going about it the right way.










      share|cite|improve this question













      Suppose we are given the followin where $f$,$u$, $g$ are given functions:



      $-Delta u = f$ in $Omega$



      $u=u_o$ on $Gamma_1$



      $frac{du}{dn}=g$ on $Gamma_2$



      So in order for me to form the variational problem which is the first step, I did the following.



      Assume $u_o$ is sufficiently smooth on $hat{Gamma}$ then, $hat{u}=u-u_o$



      This results in:



      $-Delta hat{u}= f$ in $hat{Omega}$



      $hat{u}=0$ on $hat{Gamma_1}$



      $frac{dhat{u}}{dn}=g-frac{du_o}{dn}$



      If I let $V$={$v in H^1(Omega): v|_{Gamma_1} = 0$}



      Then by applying my test function v and using Green's Formula, I can show that the new problem I've created is similar to the original problem and it results in:



      $int_{Omega} nabla u nabla vdx$ = $int_{Omega}fvdx+int_{Gamma_2}gv ds $



      where the bilinear case is $a<u,v> = int_{Omega} nabla u nabla vdx$



      the linear case is $L(v) = int_{Omega}fvdx+int_{Gamma_2}gv ds $



      So now that I have gotten the variational problem finished I need to implement some finite element method.



      So this would mean I need to find a basis function which I would pick a triangulation in some smaller subspace $V_h=${$v_h$ is continous, linear.},



      $phi_j(x)= 1$ if $i=j$ and $0$ if $ineq j$



      So then,



      $v_h=sum_{j=1}^{M} eta_j phi_j(x)$ are the linear combinations



      Now essentially I need to get to some sort of formulation of the finite element method where I would have



      $A zeta=b$ and then I could get some sort formulation of what the A matrix would look like. I know the A matrix will be symmetric and positive definite.
      I know the following,



      $A_{ij}= <phi_i' , phi_j'>$



      $b=<f, phi_i>$



      I'm stuck on the finite method part and I want to make sure I'm going about it the right way.







      finite-element-method elliptic-equations variational-analysis






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      asked Nov 17 at 20:04









      lnbmoco

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