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First implementation of 2D Cartesian space.

Browse source 
Files and types with 'Cyl' have been changed to '2DCyl' to better
differentiate between the two types of 2D geometry.

Solvers for charged and neutral particles in 2D Cartesian space.

Added solveds for 1D neutral particles (this branch is not the place to
    do it, but it was a minor change).

User Manual updated with the new accepted options.
This commit is contained in:
Jorge Gonzalez 2021-01-21 12:03:10 +01:00
commit 2ae4a6c785
14 changed files with 2110 additions and 162 deletions
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599
src/modules/mesh/2DCyl/moduleMeshCylRead.f90
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@ -1,599 +0,0 @@
MODULE moduleMeshCylRead
USE moduleMesh
USE moduleMeshCyl
TYPE, EXTENDS(meshGeneric):: meshCylGeneric
CONTAINS
PROCEDURE, PASS:: init => initCylMesh
PROCEDURE, PASS:: readMesh => readMeshCylGmsh
END TYPE
INTERFACE connected
MODULE PROCEDURE connectedVolVol, connectedVolEdge
END INTERFACE connected
CONTAINS
!Init mesh
SUBROUTINE initCylMesh(self, meshFormat)
USE moduleMesh
USE moduleErrors
IMPLICIT NONE
CLASS(meshCylGeneric), INTENT(out):: self
CHARACTER(:), ALLOCATABLE, INTENT(in):: meshFormat
SELECT CASE(meshFormat)
CASE ("gmsh")
self%printOutput => printOutputGmsh
self%printColl => printCollGmsh
self%printEM => printEMGmsh
CASE DEFAULT
CALL criticalError("Mesh type " // meshFormat // " not supported.", "initCylMesh")
END SELECT
END SUBROUTINE initCylMesh
!Read mesh from gmsh file
SUBROUTINE readMeshCylGmsh(self, filename)
USE moduleBoundary
IMPLICIT NONE
CLASS(meshCylGeneric), INTENT(inout):: self
CHARACTER(:), ALLOCATABLE, INTENT(in):: filename
REAL(8):: r, z
INTEGER:: p(1:4)
INTEGER:: e=0, et=0, n=0, eTemp=0, elemType=0, bt = 0
INTEGER:: totalNumElem
INTEGER:: boundaryType
!Read msh
OPEN(10, FILE=TRIM(filename))
!Skip header
READ(10, *)
READ(10, *)
READ(10, *)
READ(10, *)
!Read number of nodes
READ(10, *) self%numNodes
!Allocate required matrices and vectors
ALLOCATE(self%nodes(1:self%numNodes))
ALLOCATE(self%K(1:self%numNodes,1:self%numNodes))
ALLOCATE(self%IPIV(1:self%numNodes,1:self%numNodes))
self%K = 0.D0
self%IPIV = 0
!Read nodes cartesian coordinates (x=z, y=r, z=null)
DO e=1, self%numNodes
READ(10, *) n, z, r
ALLOCATE(meshNodeCyl:: self%nodes(n)%obj)
CALL self%nodes(n)%obj%init(n, (/r, z, 0.D0 /))
END DO
!Skips comments
READ(10, *)
READ(10, *)
!Reads Totalnumber of elements
READ(10, *) TotalnumElem
!counts edges and volume elements
self%numEdges = 0
DO e=1, TotalnumElem
READ(10,*) eTemp, elemType
IF (elemType==1) THEN
self%numEdges=e
END IF
END DO
!Substract the number of edges to the total number of elements
!to obtain the number of volume elements
self%numVols = TotalnumElem - self%numEdges
!Allocates arrays
ALLOCATE(self%edges(1:self%numEdges))
ALLOCATE(self%vols(1:self%numVols))
!Go back to the beggining to read elements
DO e=1, totalNumElem
BACKSPACE(10)
END DO
!Reads edges
DO e=1, self%numEdges
READ(10,*) n, elemType, eTemp, boundaryType, eTemp, p(1:2)
!Associate boundary condition procedure.
bt = getBoundaryId(boundaryType)
ALLOCATE(meshEdgeCyl:: self%edges(e)%obj)
CALL self%edges(e)%obj%init(n, p(1:2), bt, boundaryType)
END DO
!Read and initialize volumes
DO e=1, self%numVols
READ(10,*) n, elemType
BACKSPACE(10)
SELECT CASE(elemType)
CASE (2)
!Triangular element
READ(10,*) n, elemType, eTemp, eTemp, eTemp, p(1:3)
ALLOCATE(meshVolCylTria:: self%vols(e)%obj)
CALL self%vols(e)%obj%init(n - self%numEdges, p(1:3))
CASE (3)
!Quadrilateral element
READ(10,*) n, elemType, eTemp, eTemp, eTemp, p(1:4)
ALLOCATE(meshVolCylQuad:: self%vols(e)%obj)
CALL self%vols(e)%obj%init(n - self%numEdges, p(1:4))
END SELECT
END DO
CLOSE(10)
!Build connectivity between elements
DO e = 1, self%numVols
!Connectivity between volumes
DO et = 1, self%numVols
IF (e /= et) THEN
CALL connected(self%vols(e)%obj, self%vols(et)%obj)
END IF
END DO
!Connectivity between vols and edges
DO et = 1, self%numEdges
CALL connected(self%vols(e)%obj, self%edges(et)%obj)
END DO
!Constructs the global K matrix
CALL constructGlobalK(self%K, self%vols(e)%obj)
END DO
END SUBROUTINE readMeshCylGmsh
!Selects type of elements to build connection
SUBROUTINE connectedVolVol(elemA, elemB)
IMPLICIT NONE
CLASS(meshVol), INTENT(inout):: elemA
CLASS(meshVol), INTENT(inout):: elemB
SELECT TYPE(elemA)
TYPE IS(meshVolCylQuad)
!Element A is a quadrilateral
SELECT TYPE(elemB)
TYPE IS(meshVolCylQuad)
!Element B is a quadrilateral
CALL connectedQuadQuad(elemA, elemB)
TYPE IS(meshVolCylTria)
!Element B is a triangle
CALL connectedQuadTria(elemA, elemB)
END SELECT
TYPE IS(meshVolCylTria)
!Element A is a Triangle
SELECT TYPE(elemB)
TYPE IS(meshVolCylQuad)
!Element B is a quadrilateral
CALL connectedQuadTria(elemB, elemA)
TYPE IS(meshVolCylTria)
!Element B is a triangle
CALL connectedTriaTria(elemA, elemB)
END SELECT
END SELECT
END SUBROUTINE connectedVolVol
SUBROUTINE connectedVolEdge(elemA, elemB)
IMPLICIT NONE
CLASS(meshVol), INTENT(inout):: elemA
CLASS(meshEdge), INTENT(inout):: elemB
SELECT TYPE(elemB)
CLASS IS(meshEdgeCyl)
SELECT TYPE(elemA)
TYPE IS(meshVolCylQuad)
!Element A is a quadrilateral
CALL connectedQuadEdge(elemA, elemB)
TYPE IS(meshVolCylTria)
!Element A is a triangle
CALL connectedTriaEdge(elemA, elemB)
END SELECT
END SELECT
END SUBROUTINE connectedVolEdge
SUBROUTINE connectedQuadQuad(elemA, elemB)
IMPLICIT NONE
CLASS(meshVolCylQuad), INTENT(inout), TARGET:: elemA
CLASS(meshVolCylQuad), INTENT(inout), TARGET:: elemB
!Check direction 1
IF (.NOT. ASSOCIATED(elemA%e1) .AND. &
elemA%n1%n == elemB%n4%n .AND. &
elemA%n2%n == elemB%n3%n) THEN
elemA%e1 => elemB
elemB%e3 => elemA
END IF
!Check direction 2
IF (.NOT. ASSOCIATED(elemA%e2) .AND. &
elemA%n2%n == elemB%n1%n .AND. &
elemA%n3%n == elemB%n4%n) THEN
elemA%e2 => elemB
elemB%e4 => elemA
END IF
!Check direction 3
IF (.NOT. ASSOCIATED(elemA%e3) .AND. &
elemA%n3%n == elemB%n2%n .AND. &
elemA%n4%n == elemB%n1%n) THEN
elemA%e3 => elemB
elemB%e1 => elemA
END IF
!Check direction 4
IF (.NOT. ASSOCIATED(elemA%e4) .AND. &
elemA%n4%n == elemB%n3%n .AND. &
elemA%n1%n == elemB%n2%n) THEN
elemA%e4 => elemB
elemB%e2 => elemA
END IF
END SUBROUTINE connectedQuadQuad
SUBROUTINE connectedQuadTria(elemA, elemB)
IMPLICIT NONE
CLASS(meshVolCylQuad), INTENT(inout), TARGET:: elemA
CLASS(meshVolCylTria), INTENT(inout), TARGET:: elemB
!Check direction 1
IF (.NOT. ASSOCIATED(elemA%e1)) THEN
IF (elemA%n1%n == elemB%n1%n .AND. &
elemA%n2%n == elemB%n3%n) THEN
elemA%e1 => elemB
elemB%e3 => elemA
ELSEIF (elemA%n1%n == elemB%n3%n .AND. &
elemA%n2%n == elemB%n2%n) THEN
elemA%e1 => elemB
elemB%e2 => elemA
ELSEIF (elemA%n1%n == elemB%n2%n .AND. &
elemA%n2%n == elemB%n1%n) THEN
elemA%e1 => elemB
elemB%e1 => elemA
END IF
END IF
!Check direction 2
IF (.NOT. ASSOCIATED(elemA%e2)) THEN
IF (elemA%n2%n == elemB%n1%n .AND. &
elemA%n3%n == elemB%n3%n) THEN
elemA%e2 => elemB
elemB%e3 => elemA
ELSEIF (elemA%n2%n == elemB%n3%n .AND. &
elemA%n3%n == elemB%n2%n) THEN
elemA%e2 => elemB
elemB%e2 => elemA
ELSEIF (elemA%n2%n == elemB%n2%n .AND. &
elemA%n3%n == elemB%n1%n) THEN
elemA%e2 => elemB
elemB%e1 => elemA
END IF
END IF
!Check direction 3
IF (.NOT. ASSOCIATED(elemA%e3)) THEN
IF (elemA%n3%n == elemB%n1%n .AND. &
elemA%n4%n == elemB%n3%n) THEN
elemA%e3 => elemB
elemB%e3 => elemA
ELSEIF (elemA%n3%n == elemB%n3%n .AND. &
elemA%n4%n == elemB%n2%n) THEN
elemA%e3 => elemB
elemB%e2 => elemA
ELSEIF (elemA%n3%n == elemB%n2%n .AND. &
elemA%n4%n == elemB%n1%n) THEN
elemA%e3 => elemB
elemB%e1 => elemA
END IF
END IF
!Check direction 4
IF (.NOT. ASSOCIATED(elemA%e4)) THEN
IF (elemA%n4%n == elemB%n1%n .AND. &
elemA%n1%n == elemB%n3%n) THEN
elemA%e4 => elemB
elemB%e3 => elemA
ELSEIF (elemA%n4%n == elemB%n3%n .AND. &
elemA%n1%n == elemB%n2%n) THEN
elemA%e4 => elemB
elemB%e2 => elemA
ELSEIF (elemA%n4%n == elemB%n2%n .AND. &
elemA%n1%n == elemB%n1%n) THEN
elemA%e4 => elemB
elemB%e1 => elemA
END IF
END IF
END SUBROUTINE connectedQuadTria
SUBROUTINE connectedTriaTria(elemA, elemB)
IMPLICIT NONE
CLASS(meshVolCylTria), INTENT(inout), TARGET:: elemA
CLASS(meshVolCylTria), INTENT(inout), TARGET:: elemB
!Check direction 1
IF (.NOT. ASSOCIATED(elemA%e1)) THEN
IF (elemA%n1%n == elemB%n1%n .AND. &
elemA%n2%n == elemB%n3%n) THEN
elemA%e1 => elemB
elemB%e3 => elemA
ELSEIF (elemA%n1%n == elemB%n2%n .AND. &
elemA%n2%n == elemB%n1%n) THEN
elemA%e1 => elemB
elemB%e1 => elemA
ELSEIF (elemA%n1%n == elemB%n3%n .AND. &
elemA%n2%n == elemB%n2%n) THEN
elemA%e1 => elemB
elemB%e2 => elemA
END IF
END IF
!Check direction 2
IF (.NOT. ASSOCIATED(elemA%e2)) THEN
IF (elemA%n2%n == elemB%n1%n .AND. &
elemA%n3%n == elemB%n3%n) THEN
elemA%e2 => elemB
elemB%e3 => elemA
ELSEIF (elemA%n2%n == elemB%n2%n .AND. &
elemA%n3%n == elemB%n1%n) THEN
elemA%e2 => elemB
elemB%e1 => elemA
ELSEIF (elemA%n2%n == elemB%n3%n .AND. &
elemA%n3%n == elemB%n2%n) THEN
elemA%e2 => elemB
elemB%e2 => elemA
END IF
END IF
!Check direction 3
IF (.NOT. ASSOCIATED(elemA%e3)) THEN
IF (elemA%n3%n == elemB%n1%n .AND. &
elemA%n1%n == elemB%n3%n) THEN
elemA%e3 => elemB
elemB%e3 => elemA
ELSEIF (elemA%n3%n == elemB%n2%n .AND. &
elemA%n1%n == elemB%n1%n) THEN
elemA%e3 => elemB
elemB%e1 => elemA
ELSEIF (elemA%n3%n == elemB%n3%n .AND. &
elemA%n1%n == elemB%n2%n) THEN
elemA%e3 => elemB
elemB%e2 => elemA
END IF
END IF
END SUBROUTINE connectedTriaTria
SUBROUTINE connectedQuadEdge(elemA, elemB)
IMPLICIT NONE
CLASS(meshVolCylQuad), INTENT(inout), TARGET:: elemA
CLASS(meshEdgeCyl), INTENT(inout), TARGET:: elemB
!Check direction 1
IF (.NOT. ASSOCIATED(elemA%e1)) THEN
IF (elemA%n1%n == elemB%n1%n .AND. &
elemA%n2%n == elemB%n2%n) THEN
elemA%e1 => elemB
elemB%e2 => elemA
ELSEIF (elemA%n1%n == elemB%n2%n .AND. &
elemA%n2%n == elemB%n1%n) THEN
elemA%e1 => elemB
elemB%e1 => elemA
END IF
END IF
!Check direction 2
IF (.NOT. ASSOCIATED(elemA%e2)) THEN
IF (elemA%n2%n == elemB%n1%n .AND. &
elemA%n3%n == elemB%n2%n) THEN
elemA%e2 => elemB
elemB%e2 => elemA
ELSEIF (elemA%n2%n == elemB%n2%n .AND. &
elemA%n3%n == elemB%n1%n) THEN
elemA%e2 => elemB
elemB%e1 => elemA
END IF
END IF
!Check direction 3
IF (.NOT. ASSOCIATED(elemA%e3)) THEN
IF (elemA%n3%n == elemB%n1%n .AND. &
elemA%n4%n == elemB%n2%n) THEN
elemA%e3 => elemB
elemB%e2 => elemA
ELSEIF (elemA%n3%n == elemB%n2%n .AND. &
elemA%n4%n == elemB%n1%n) THEN
elemA%e3 => elemB
elemB%e1 => elemA
END IF
END IF
!Check direction 4
IF (.NOT. ASSOCIATED(elemA%e4)) THEN
IF (elemA%n4%n == elemB%n1%n .AND. &
elemA%n1%n == elemB%n2%n) THEN
elemA%e4 => elemB
elemB%e2 => elemA
ELSEIF (elemA%n4%n == elemB%n2%n .AND. &
elemA%n1%n == elemB%n1%n) THEN
elemA%e4 => elemB
elemB%e1 => elemA
END IF
END IF
END SUBROUTINE connectedQuadEdge
SUBROUTINE connectedTriaEdge(elemA, elemB)
IMPLICIT NONE
CLASS(meshVolCylTria), INTENT(inout), TARGET:: elemA
CLASS(meshEdgeCyl), INTENT(inout), TARGET:: elemB
!Check direction 1
IF (.NOT. ASSOCIATED(elemA%e1)) THEN
IF (elemA%n1%n == elemB%n1%n .AND. &
elemA%n2%n == elemB%n2%n) THEN
elemA%e1 => elemB
elemB%e2 => elemA
ELSEIF (elemA%n1%n == elemB%n2%n .AND. &
elemA%n2%n == elemB%n1%n) THEN
elemA%e1 => elemB
elemB%e1 => elemA
END IF
END IF
!Check direction 2
IF (.NOT. ASSOCIATED(elemA%e2)) THEN
IF (elemA%n2%n == elemB%n1%n .AND. &
elemA%n3%n == elemB%n2%n) THEN
elemA%e2 => elemB
elemB%e2 => elemA
ELSEIF (elemA%n2%n == elemB%n2%n .AND. &
elemA%n3%n == elemB%n1%n) THEN
elemA%e2 => elemB
elemB%e1 => elemA
END IF
END IF
!Check direction 3
IF (.NOT. ASSOCIATED(elemA%e3)) THEN
IF (elemA%n3%n == elemB%n1%n .AND. &
elemA%n1%n == elemB%n2%n) THEN
elemA%e3 => elemB
elemB%e2 => elemA
ELSEIF (elemA%n3%n == elemB%n2%n .AND. &
elemA%n1%n == elemB%n1%n) THEN
elemA%e3 => elemB
elemB%e1 => elemA
END IF
END IF
END SUBROUTINE connectedTriaEdge
SUBROUTINE constructGlobalK(K, elem)
IMPLICIT NONE
REAL(8), INTENT(inout):: K(1:,1:)
CLASS(meshVol), INTENT(in):: elem
REAL(8), ALLOCATABLE:: localK(:,:)
INTEGER:: nNodes, i, j
INTEGER, ALLOCATABLE:: n(:)
SELECT TYPE(elem)
TYPE IS(meshVolCylQuad)
nNodes = 4
ALLOCATE(localK(1:nNodes,1:nNodes))
localK = elem%elemK()
ALLOCATE(n(1:nNodes))
n = (/ elem%n1%n, elem%n2%n, &
elem%n3%n, elem%n4%n /)
TYPE IS(meshVolCylTria)
nNodes = 3
ALLOCATE(localK(1:nNodes,1:nNodes))
localK = elem%elemK()
ALLOCATE(n(1:nNodes))
n = (/ elem%n1%n, elem%n2%n, elem%n3%n /)
CLASS DEFAULT
nNodes = 0
ALLOCATE(localK(1:1, 1:1))
localK = 0.D0
ALLOCATE(n(1:1))
n = 0
END SELECT
DO i = 1, nNodes
DO j = 1, nNodes
K(n(i), n(j)) = K(n(i), n(j)) + localK(i, j)
END DO
END DO
END SUBROUTINE constructGlobalK
END MODULE moduleMeshCylRead