TVB斜率限制器

本文参考源程序来自Fluidity。

简介

TVB斜率限制器最早由Cockburn和Shu（1989）提出，主要特点是提出了修正minmod函数

[ ilde{m}(a_1, a_2, cdots, a_n) = left{ egin{array}{ll} a_1 & ext{if} \, left| a_1 ight| le Mh^2, cr mleft(a_1, a_2, cdots, a_n ight) & ext{otherwise}, end{array} ight.]

其中(mleft(a_1, a_2, cdots, a_n ight))为原始minmod函数，(M)为系数。

高维TVB限制器

针对高维情形可以参考Cockburn和Shu[2]的研究，高维情形与一维类似，但是主要区别在于构造修正minmod函数的两个参数

[egin{equation} a_1 = ilde{u}_h(m_i, K_0), quad a_2 = vDeltaar{u}_h(m_i, K_0) end{equation}]

其中 ( ilde{u}_h(m_i, K_0)) 为边界中点处近似解与单元均值之差 (u_h(m_i, K_0) - ar{u}_{K_0})，(ar{u}_{K_0}) 为单元 (K_0) 的单元均值。而这个 (Deltaar{u}_h(m_i, K_0)) 则是根据几何坐标插值后得到的边界中心值 (u_h(m_1)) 与 (ar{u}_{K_0}) 之间差值，(v) 为大于1的系数，一般取1.5左右。

几何插值系数根据三个单元间坐标关系而定。如在计算边中点 (m_1) 的系数时，首先需确定除 (b_0) 和 (b_1) 外要取哪个单元进行插值（(b_2) 或 (b_3)），其中选取原则为以下两点

单元 (b_1) 所占比例尽量大
中点 (m_1) 尽量在两条射线 (b_0 - b_1) 与 (b_0 - b_2) 之间

在确定第三个单元之后，我们便可以确定中点 (m_1) 插值系数。插值公式为

[egin{equation} u_h(m_1) - u_h(b_0) = alpha_1 left( u_h(b_1) - u_h(b_0) ight) + alpha_2 left( u_h(b_2) - u_h(b_0) ight) end{equation}]

其中插值系数根据三个三角形单元形心坐标而定

[egin{equation} left{ egin{array}{ll} x_{m_1} - x_{b_0} = alpha_1 left( x_{b_1} - x_{b_0} ight) + alpha_2 left( x_{b_2} - x_{b_0} ight) cr y_{m_1} - y_{b_0} = alpha_1 left( y_{b_1} - y_{b_0} ight) + alpha_2 left( y_{b_2} - y_{b_0} ight) end{array} ight. end{equation}]

在得到修正后的边界值与均值之差后，修正过程并没有结束。因为可能TVB限制器只修正了三个边中某两个边中点值，而剩下的边中点值保持不变，若此时采用新的三个边中点值进行重构，得到的重构值均值区别于原始单元均值，造成单元不守恒。

为解决此问题，需要对修正后的插值进行修正。假设 (Delta_i) 为限制器得到的解

[egin{equation} Delta_i = ilde{m}left( ilde{u}_h(m_i, K_0), vDeltaar{u}_h(m_i, K_0) ight) end{equation}]

由于 (Delta_i) 代表限制后边界中点值与单元均值之差，因此应当满足 (sum_{i=1}^3 Delta_i = 0)。若 (sum_{i=1}^3 Delta_i eq 0)，计算修正系数 ( heta^+) 与 ( heta^-)

[egin{equation} egin{array}{ll} pos = sum_{i=1}^3 ext{max} left(0, Delta_i ight), quad neg = sum_{i=1}^3 ext{max} left(0, -Delta_i ight) cr heta^+ = ext{min} left(1, frac{neg}{pos} ight), quad heta^- = ext{min} left(1, frac{pos}{neg} ight) end{array} end{equation}]

其中 (pos) 与 (neg) 分别是 (Delta_i) 中正系数与负系数总和。采用 ( heta^+) 与 ( heta^-) 修正后限制值为

[egin{equation} hat{Delta}_i = heta^+ ext{max} left(0, Delta_i ight) - heta^- ext{max} left(0, -Delta_i ight) end{equation}]

此时满足 (sum_{i=1}^3 hat{Delta}_i = 0)，根据 (hat{Delta}_i) 进行重构便可得到限制后的解。

代码

源程序文件为/assemble/Slope_limiters_DG.F90。

subroutine cockburn_shu_setup_ele(ele, T, X)
integer, intent(in) :: ele
type(scalar_field), intent(inout) :: T
type(vector_field), intent(in) :: X

integer, dimension(:), pointer :: neigh, x_neigh
real, dimension(X%dim) :: ele_centre, face_2_centre
real :: max_alpha, min_alpha, neg_alpha
integer :: ele_2, ni, nj, face, face_2, i, nk, ni_skip, info, nl
real, dimension(X%dim, ele_loc(X,ele)) :: X_val, X_val_2
real, dimension(X%dim, ele_face_count(T,ele)) :: neigh_centre,&
     & face_centre
real, dimension(X%dim) :: alpha1, alpha2
real, dimension(X%dim,X%dim) :: alphamat
real, dimension(X%dim,X%dim+1) :: dx_f, dx_c
integer, dimension(mesh_dim(T)) :: face_nodes

X_val=ele_val(X, ele)

ele_centre=sum(X_val,2)/size(X_val,2)

neigh=>ele_neigh(T, ele)
! x_neigh/=t_neigh only on periodic boundaries.
x_neigh=>ele_neigh(X, ele)

searchloop: do ni=1,size(neigh)

   !----------------------------------------------------------------------
   ! Find the relevant faces.
   !----------------------------------------------------------------------
   ele_2=neigh(ni)

   ! Note that although face is calculated on field U, it is in fact
   ! applicable to any field which shares the same mesh topology.
   face=ele_face(T, ele, ele_2)
   face_nodes=face_local_nodes(T, face)

   face_centre(:,ni) = sum(X_val(:,face_nodes),2)/size(face_nodes)
   
   if (ele_2<=0) then
      ! External face.
      neigh_centre(:,ni)=face_centre(:,ni)
      cycle
   end if

   X_val_2=ele_val(X, ele_2)
   
   neigh_centre(:,ni)=sum(X_val_2,2)/size(X_val_2,2)
   if (ele_2/=x_neigh(ni)) then
      ! Periodic boundary case. We have to cook up the coordinate by
      ! adding vectors to the face from each side.
      face_2=ele_face(T, ele_2, ele)
      face_2_centre = &
           sum(face_val(X,face_2),2)/size(face_val(X,face_2),2)
      neigh_centre(:,ni)=face_centre(:,ni) + &
           (neigh_centre(:,ni) - face_2_centre)
   end if

end do searchloop

do ni = 1, size(neigh)
   dx_c(:,ni)=neigh_centre(:,ni)-ele_centre !Vectors from ni centres to
   !                                         !ele centre
   dx_f(:,ni)=face_centre(:,ni)-ele_centre !Vectors from ni face centres
                                          !to ele centre
end do

alpha_construction_loop: do ni = 1, size(neigh)
   !Loop for constructing Delta v(m_i,K_0) as described in C&S
   alphamat(:,1) = dx_c(:,ni)

   max_alpha = -1.0
   ni_skip = 0

   choosing_best_other_face_loop: do nj = 1, size(neigh)
      !Loop over the other faces to choose best one to use
      !for linear basis across face

      if(nj==ni) cycle
      
      !Construct a linear basis using all faces except for nj
      nl = 1
      do nk = 1, size(neigh)
         if(nk==nj.or.nk==ni) cycle
         nl = nl + 1
         alphamat(:,nl) = dx_c(:,nk)
      end do
      
      !Solve for basis coefficients alpha
      alpha2 = dx_f(:,ni)
      call solve(alphamat,alpha2,info)

      if((.not.any(alpha2<0.0)).and.alpha2(1)/norm2(alpha2)>max_alpha) &
           & then
         alpha1 = alpha2
         ni_skip = nj
         max_alpha = alpha2(1)/norm2(alpha2)
      end if

   end do choosing_best_other_face_loop

   if(max_alpha<0.0) then
      if(tolerate_negative_weights) then
         min_alpha = huge(0.0)
         ni_skip = 0
         choosing_best_other_face_neg_weights_loop: do nj = 1, size(neigh)
            !Loop over the other faces to choose best one to use
            !for linear basis across face
            
            if(nj==ni) cycle
            
            !Construct a linear basis using all faces except for nj
            nl = 1
            do nk = 1, size(neigh)
               if(nk==nj.or.nk==ni) cycle
               nl = nl + 1
               alphamat(:,nl) = dx_c(:,nk)
            end do
            
            !Solve for basis coefficients alpha
            alpha2 = dx_f(:,ni)
            call solve(alphamat,alpha2,info)

            neg_alpha = 0.0
            do i = 1, size(alpha2)
               if(alpha2(i)<0.0) then
                  neg_alpha = neg_alpha + alpha2(i)**2
               end if
            end do
            neg_alpha = sqrt(neg_alpha)

            if(min_alpha>neg_alpha) then
               alpha1 = alpha2
               ni_skip = nj
               min_alpha = neg_alpha
            end if
         end do choosing_best_other_face_neg_weights_loop
      else
         FLAbort('solving for alpha failed')
      end if
   end if
   
   alpha(ele,ni,:) = 0.0
   alpha(ele,ni,ni) = alpha1(1)
   nl = 1
   do nj = 1, size(neigh)
      if(nj==ni.or.nj==ni_skip) cycle
      nl = nl + 1
      alpha(ele,ni,nj) = alpha1(nl)
   end do

   dx2(ele,ni) = norm2(dx_c(:,ni))

end do alpha_construction_loop

end subroutine cockburn_shu_setup_ele

subroutine limit_slope_ele_cockburn_shu(ele, T, X)
!!< Slope limiter according to Cockburn and Shu (2001) 
!!< http://dx.doi.org/10.1023/A:1012873910884
integer, intent(in) :: ele
type(scalar_field), intent(inout) :: T
type(vector_field), intent(in) :: X

integer, dimension(:), pointer :: neigh, x_neigh, T_ele
real :: ele_mean
real :: pos, neg
integer :: ele_2, ni, face
real, dimension(ele_loc(T,ele)) :: T_val, T_val_2
real, dimension(ele_face_count(T,ele)) :: neigh_mean, face_mean
real, dimension(mesh_dim(T)+1) :: delta_v
real, dimension(mesh_dim(T)+1) :: Delta, new_val
integer, dimension(mesh_dim(T)) :: face_nodes

T_val=ele_val(T, ele)

ele_mean=sum(T_val)/size(T_val)

neigh=>ele_neigh(T, ele)
! x_neigh/=t_neigh only on periodic boundaries.
x_neigh=>ele_neigh(X, ele)

searchloop: do ni=1,size(neigh)

   !----------------------------------------------------------------------
   ! Find the relevant faces.
   !----------------------------------------------------------------------
   ele_2=neigh(ni)

   ! Note that although face is calculated on field U, it is in fact
   ! applicable to any field which shares the same mesh topology.
   face=ele_face(T, ele, ele_2)
   face_nodes=face_local_nodes(T, face)
   
   face_mean(ni) = sum(T_val(face_nodes))/size(face_nodes)
   
   if (ele_2<=0) then
      ! External face.
      neigh_mean(ni)=face_mean(ni)
      cycle
   end if

   T_val_2=ele_val(T, ele_2)

   neigh_mean(ni)=sum(T_val_2)/size(T_val_2)

end do searchloop

delta_v = matmul(alpha(ele,:,:),neigh_mean-ele_mean)

delta_loop: do ni=1,size(neigh)

   Delta(ni)=TVB_minmod(face_mean(ni)-ele_mean, &
        Limit_factor*delta_v(ni), dx2(ele,ni))

end do delta_loop

if (abs(sum(Delta))>1000.0*epsilon(0.0)) then
   ! Coefficients do not sum to 0.0

   pos=sum(max(0.0, Delta))
   neg=sum(max(0.0, -Delta))
   
   Delta = min(1.0,neg/pos)*max(0.0,Delta) &
        -min(1.0,pos/neg)*max(0.0,-Delta)
   
end if

new_val=matmul(A,Delta+ele_mean)

! Success or non-boundary failure.
T_ele=>ele_nodes(T,ele)

call set(T, T_ele, new_val)

end subroutine limit_slope_ele_cockburn_shu

[1] COCKBURN B, SHU C-W. TVB Runge-Kutta local projection discontinuous Galerkin finite element method for conservation laws. II. General framework[J]. Mathematics of Computation, 1989, 52(186): 411–411.

[2] COCKBURN B, SHU C-W. The Runge-Kutta discontinuous Galerkin method for conservation laws. V. Multidimensional systems[J]. Journal of Computational Physics, 1998, 141(2): 199–224.