I think I have it, and I think that the averaring might not be required

2026-05-04 12:10:50 +02:00 · 2026-05-04 12:10:50 +02:00 · b016833876
commit b016833876
parent a174a50b81
3 changed files with 26 additions and 12 deletions
--- a/src/modules/init/moduleInput.f90
+++ b/src/modules/init/moduleInput.f90
@ -1351,6 +1351,8 @@ MODULE moduleInput
                bound%nEdges = size(bound%edges)
                allocate(bound%electricField(1:bound%nEdges))
                bound%electricField = 0.0d0
+                allocate(bound%deltaElectricField(1:bound%nEdges))
+                bound%deltaElectricField = 0.0d0

              end if

--- a/src/modules/mesh/moduleMesh.f90
+++ b/src/modules/mesh/moduleMesh.f90
@ -1118,6 +1118,7 @@ MODULE moduleMesh
    integer:: nEdges
    type(meshEdgePointer), allocatable:: edges(:) ! Edges included in the boundary
    real(8), allocatable:: electricField(:) ! Electric field normal to the edge that must be applied with a Neumann boundary condition
+    real(8), allocatable:: deltaElectricField(:) ! Accumulated change in E
    integer:: counter
    contains
      procedure, pass:: apply => applyFreeCurrent
--- a/src/modules/mesh/moduleMesh@boundaryEM.f90
+++ b/src/modules/mesh/moduleMesh@boundaryEM.f90
@ -367,6 +367,7 @@ submodule(moduleMesh) boundaryEM
    ! Update
    subroutine updateFreeCurrent(self)
      use moduleCaseParam, only: tauMin
+      use moduleRefParam, only: Vol_ref, n_ref
      implicit none

      class(boundaryEMGeneric), intent(inout):: self
@ -376,13 +377,19 @@ submodule(moduleMesh) boundaryEM
      real(8), allocatable:: den_nodes(:)
      class(meshNode), pointer:: node
      real(8):: mom_center, den_center, charge_center
-      real(8):: vel_avg_center
+      real(8):: l_c ! Characteristic length
+      integer:: every
+      real(8):: every_inv
+
+      ! TODO: Make this an input parameter
+      every = 10
+      every_inv = 1.0d0 / real(every)

      select type(self)
      type is(boundaryEMFreeCurrent)
        self%counter = self%counter + 1
-        do e=1, self%nEdges

+        do e=1, self%nEdges
          mom_center    = 0.0d0
          den_center    = 0.0d0
          charge_center = 0.0d0
@ -392,16 +399,14 @@ submodule(moduleMesh) boundaryEM
            nodes = edge%getNodes(edge%nNodes)
            allocate(mom_nodes(1:edge%nNodes))
            allocate(den_nodes(1:edge%nNodes))
-            mom_nodes = 0.0d0
-            den_nodes = 0.0d0

            do s = 1, nSpecies
              do n = 1, self%nNodes
                node => mesh%nodes(nodes(n))%obj

                ! Minus sign as we look at the values exiting the surface (opposite to the normal) 
-                mom_nodes(n) = - dot_product(node%output(s)%mom, edge%normal)
-                den_nodes(n) =   node%output(s)%den
+                mom_nodes(n) = - dot_product(node%output(s)%mom, edge%normal)/(node%v*Vol_ref*n_ref)
+                den_nodes(n) =   node%output(s)%den/(node%v*Vol_ref*n_ref)

              end do

@ -412,20 +417,26 @@ submodule(moduleMesh) boundaryEM
            end do

            if (den_center > 1.0e-10) then
-              vel_avg_center = mom_center / den_center
-            else
-              vel_avg_center = 0.0d0
+              self%deltaElectricField(e) = self%deltaElectricField(e) + mom_center * charge_center / den_center * tauMin

            end if

+            deallocate(nodes, mom_nodes, den_nodes)
+
          end associate

-          self%electricField(e) = self%electricField(e) - vel_avg_center*charge_center*tauMin
-
-          deallocate(nodes, mom_nodes, den_nodes)

        end do

+        if (self%counter == every) then
+
+          self%electricField = self%electricField - self%deltaElectricField*every_inv
+
+          ! reset for the next iteration
+          self%counter = 0
+          self%deltaElectricField = 0.0d0
+
+        end if

      end select