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First implementation of 1D radial case. Only charged particles taked

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into account (as in 1D Cartesian case).

The 1D Cathode example case has been modified, having now 2 input files:
  - inputCart.json: Used for Cartesian coordinates
  - inputRad.json:  Used for Radial coordinates

Pusher is a Boris pusher but without z direction.
This commit is contained in:
Jorge Gonzalez 2020-12-13 22:14:37 +01:00
commit d3d070a367
15 changed files with 1024 additions and 109 deletions
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src/modules/mesh/1DCart/moduleMesh1DCart.f90 Normal file
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!moduleMesh1D: 1D cartesian module
! x == x
! y == unused
! z == unused
MODULE moduleMesh1DCart
USE moduleMesh
IMPLICIT NONE
TYPE, PUBLIC, EXTENDS(meshNode):: meshNode1DCart
!Element coordinates
REAL(8):: x = 0.D0
CONTAINS
PROCEDURE, PASS:: init => initNode1DCart
PROCEDURE, PASS:: getCoordinates => getCoord1DCart
END TYPE meshNode1DCart
TYPE, PUBLIC, ABSTRACT, EXTENDS(meshEdge):: meshEdge1DCart
!Element coordinates
REAL(8):: x = 0.D0
!Connectivity to nodes
CLASS(meshNode), POINTER:: n1 => NULL()
CONTAINS
PROCEDURE, PASS:: init => initEdge1DCart
PROCEDURE, PASS:: getNodes => getNodes1DCart
PROCEDURE, PASS:: randPos => randPos1DCart
END TYPE meshEdge1DCart
TYPE, PUBLIC, ABSTRACT, EXTENDS(meshVol):: meshVol1DCart
CONTAINS
PROCEDURE, PASS:: detJac => detJ1DCart
PROCEDURE, PASS:: invJac => invJ1DCart
PROCEDURE(fPsi_interface), DEFERRED, NOPASS:: fPsi
PROCEDURE(dPsi_interface), DEFERRED, NOPASS:: dPsi
PROCEDURE(partialDer_interface), DEFERRED, PASS:: partialDer
END TYPE meshVol1DCart
ABSTRACT INTERFACE
PURE FUNCTION fPsi_interface(xi) RESULT(fPsi)
REAL(8), INTENT(in):: xi(1:3)
REAL(8), ALLOCATABLE:: fPsi(:)
END FUNCTION fPsi_interface
PURE FUNCTION dPsi_interface(xi) RESULT(dPsi)
REAL(8), INTENT(in):: xi(1:3)
REAL(8), ALLOCATABLE:: dPsi(:,:)
END FUNCTION dPsi_interface
PURE SUBROUTINE partialDer_interface(self, dPsi, dx)
IMPORT meshVol1DCart
CLASS(meshVol1DCart), INTENT(in):: self
REAL(8), INTENT(in):: dPsi(1:,1:)
REAL(8), INTENT(out), DIMENSION(1):: dx
END SUBROUTINE partialDer_interface
END INTERFACE
TYPE, PUBLIC, EXTENDS(meshVol1DCart):: meshVol1DCartSegm
!Element coordinates
REAL(8):: x(1:2)
!Connectivity to nodes
CLASS(meshNode), POINTER:: n1 => NULL(), n2 => NULL()
!Connectivity to adjacent elements
CLASS(*), POINTER:: e1 => NULL(), e2 => NULL()
REAL(8):: arNodes(1:2)
CONTAINS
PROCEDURE, PASS:: init => initVol1DCartSegm
PROCEDURE, PASS:: area => areaSegm
PROCEDURE, NOPASS:: fPsi => fPsiSegm
PROCEDURE, NOPASS:: dPsi => dPsiSegm
PROCEDURE, PASS:: partialDer => partialDerSegm
PROCEDURE, PASS:: elemK => elemKSegm
PROCEDURE, PASS:: elemF => elemFSegm
PROCEDURE, NOPASS:: weight => weightSegm
PROCEDURE, NOPASS:: inside => insideSegm
PROCEDURE, PASS:: scatter => scatterSegm
PROCEDURE, PASS:: gatherEF => gatherEFSegm
PROCEDURE, PASS:: getNodes => getNodesSegm
PROCEDURE, PASS:: phy2log => phy2logSegm
PROCEDURE, PASS:: nextElement => nextElementSegm
PROCEDURE, PASS:: resetOutput => resetOutputSegm
END TYPE meshVol1DCartSegm
CONTAINS
!NODE FUNCTIONS
!Init node element
SUBROUTINE initNode1DCart(self, n, r)
USE moduleSpecies
USE moduleRefParam
IMPLICIT NONE
CLASS(meshNode1DCart), INTENT(out):: self
INTEGER, INTENT(in):: n
REAL(8), INTENT(in):: r(1:3)
self%n = n
self%x = r(1)/L_ref
!Node volume, to be determined in mesh
self%v = 0.D0
!Allocates output
ALLOCATE(self%output(1:nSpecies))
END SUBROUTINE initNode1DCart
PURE FUNCTION getCoord1DCart(self) RESULT(r)
IMPLICIT NONE
CLASS(meshNode1DCart), INTENT(in):: self
REAL(8):: r(1:3)
r = (/ self%x, 0.D0, 0.D0 /)
END FUNCTION getCoord1DCart
!EDGE FUNCTIONS
!Inits edge element
SUBROUTINE initEdge1DCart(self, n, p, bt, physicalSurface)
IMPLICIT NONE
CLASS(meshEdge1DCart), INTENT(out):: self
INTEGER, INTENT(in):: n
INTEGER, INTENT(in):: p(:)
INTEGER, INTENT(in):: bt
INTEGER, INTENT(in):: physicalSurface
REAL(8), DIMENSION(1:3):: r1
self%n = n
self%n1 => mesh%nodes(p(1))%obj
!Get element coordinates
r1 = self%n1%getCoordinates()
self%x = r1(1)
self%normal = (/ 1.D0, 0.D0, 0.D0 /)
!Boundary index
self%bt = bt
!Physical Surface
self%physicalSurface = physicalSurface
END SUBROUTINE initEdge1DCart
!Get nodes from edge
PURE FUNCTION getNodes1DCart(self) RESULT(n)
IMPLICIT NONE
CLASS(meshEdge1DCart), INTENT(in):: self
INTEGER, ALLOCATABLE:: n(:)
ALLOCATE(n(1))
n = (/ self%n1%n /)
END FUNCTION getNodes1DCart
!Calculates a 'random' position in edge
FUNCTION randPos1DCart(self) RESULT(r)
CLASS(meshEdge1DCart), INTENT(in):: self
REAL(8):: r(1:3)
r = (/ self%x, 0.D0, 0.D0 /)
END FUNCTION randPos1DCart
!VOLUME FUNCTIONS
!SEGMENT FUNCTIONS
!Init segment element
SUBROUTINE initVol1DCartSegm(self, n, p)
USE moduleRefParam
IMPLICIT NONE
CLASS(meshVol1DCartSegm), INTENT(out):: self
INTEGER, INTENT(in):: n
INTEGER, INTENT(in):: p(:)
REAL(8), DIMENSION(1:3):: r1, r2
self%n = n
self%n1 => mesh%nodes(p(1))%obj
self%n2 => mesh%nodes(p(2))%obj
!Get element coordinates
r1 = self%n1%getCoordinates()
r2 = self%n2%getCoordinates()
self%x = (/ r1(1), r2(1) /)
!Assign node volume
CALL self%area()
self%n1%v = self%n1%v + self%arNodes(1)
self%n2%v = self%n2%v + self%arNodes(2)
self%sigmaVrelMax = sigma_ref/L_ref**2
CALL OMP_INIT_LOCK(self%lock)
END SUBROUTINE initVol1DCartSegm
!Computes element area
PURE SUBROUTINE areaSegm(self)
IMPLICIT NONE
CLASS(meshVol1DCartSegm), INTENT(inout):: self
REAL(8):: l !element length
REAL(8):: fPsi(1:2)
REAL(8):: detJ
REAL(8):: Xii(1:3)
self%volume = 0.D0
self%arNodes = 0.D0
!1 point Gauss integral
Xii = 0.D0
fPsi = self%fPsi(Xii)
detJ = self%detJac(Xii)
l = 2.D0*detJ
self%volume = l
self%arNodes = fPsi*l
END SUBROUTINE areaSegm
!Computes element functions at point xii
PURE FUNCTION fPsiSegm(xi) RESULT(fPsi)
IMPLICIT NONE
REAL(8), INTENT(in):: xi(1:3)
REAL(8), ALLOCATABLE:: fPsi(:)
ALLOCATE(fPsi(1:2))
fPsi(1) = 1.D0 - xi(1)
fPsi(2) = 1.D0 + xi(1)
fPsi = fPsi * 5.D-1
END FUNCTION fPsiSegm
!Computes element derivative shape function at Xii
PURE FUNCTION dPsiSegm(xi) RESULT(dPsi)
IMPLICIT NONE
REAL(8), INTENT(in):: xi(1:3)
REAL(8), ALLOCATABLE:: dPsi(:,:)
ALLOCATE(dPsi(1:1, 1:2))
dPsi(1, 1) = -5.D-1
dPsi(1, 2) = 5.D-1
END FUNCTION dPsiSegm
!Computes partial derivatives of coordinates
PURE SUBROUTINE partialDerSegm(self, dPsi, dx)
IMPLICIT NONE
CLASS(meshVol1DCartSegm), INTENT(in):: self
REAL(8), INTENT(in):: dPsi(1:,1:)
REAL(8), INTENT(out), DIMENSION(1):: dx
dx(1) = DOT_PRODUCT(dPsi(1,:), self%x)
END SUBROUTINE partialDerSegm
!Computes local stiffness matrix
PURE FUNCTION elemKSegm(self) RESULT(ke)
IMPLICIT NONE
CLASS(meshVol1DCartSegm), INTENT(in):: self
REAL(8):: ke(1:2,1:2)
REAL(8):: Xii(1:3)
REAL(8):: dPsi(1:1, 1:2)
REAL(8):: invJ
ke = 0.D0
Xii = (/ 0.D0, 0.D0, 0.D0 /)
dPsi = self%dPsi(Xii)
invJ = self%invJac(Xii, dPsi)
ke(1,:) = (/ dPsi(1,1)*dPsi(1,1), dPsi(1,1)*dPsi(1,2) /)
ke(2,:) = (/ dPsi(1,2)*dPsi(1,1), dPsi(1,2)*dPsi(1,2) /)
ke = 2.D0*ke*invJ
END FUNCTION elemKSegm
PURE FUNCTION elemFSegm(self, source) RESULT(localF)
IMPLICIT NONE
CLASS(meshVol1DCartSegm), INTENT(in):: self
REAL(8), INTENT(in):: source(1:)
REAL(8), ALLOCATABLE:: localF(:)
REAL(8):: fPsi(1:2)
REAL(8):: detJ
REAL(8):: Xii(1:3)
Xii = 0.D0
fPsi = self%fPsi(Xii)
detJ = self%detJac(Xii)
ALLOCATE(localF(1:2))
localF = 2.D0*DOT_PRODUCT(fPsi, source)*detJ
END FUNCTION elemFSegm
PURE FUNCTION weightSegm(xi) RESULT(w)
IMPLICIT NONE
REAL(8), INTENT(in):: xi(1:3)
REAL(8):: w(1:2)
w = fPsiSegm(xi)
END FUNCTION weightSegm
PURE FUNCTION insideSegm(xi) RESULT(ins)
IMPLICIT NONE
REAL(8), INTENT(in):: xi(1:3)
LOGICAL:: ins
ins = xi(1) >=-1.D0 .AND. &
xi(1) <= 1.D0
END FUNCTION insideSegm
SUBROUTINE scatterSegm(self, part)
USE moduleOutput
USE moduleSpecies
IMPLICIT NONE
CLASS(meshVol1DCartSegm), INTENT(in):: self
CLASS(particle), INTENT(in):: part
TYPE(outputNode), POINTER:: vertex
REAL(8):: w_p(1:2)
REAL(8):: tensorS(1:3,1:3)
w_p = self%weight(part%xi)
tensorS = outerProduct(part%v, part%v)
vertex => self%n1%output(part%sp)
vertex%den = vertex%den + part%weight*w_p(1)
vertex%mom(:) = vertex%mom(:) + part%weight*w_p(1)*part%v(:)
vertex%tensorS(:,:) = vertex%tensorS(:,:) + part%weight*w_p(1)*tensorS
vertex => self%n2%output(part%sp)
vertex%den = vertex%den + part%weight*w_p(2)
vertex%mom(:) = vertex%mom(:) + part%weight*w_p(2)*part%v(:)
vertex%tensorS(:,:) = vertex%tensorS(:,:) + part%weight*w_p(2)*tensorS
END SUBROUTINE scatterSegm
!Gathers EF at position Xii
PURE FUNCTION gatherEFSegm(self, xi) RESULT(EF)
IMPLICIT NONE
CLASS(meshVol1DCartSegm), INTENT(in):: self
REAL(8), INTENT(in):: xi(1:3)
REAL(8):: dPsi(1, 1:2)
REAL(8):: phi(1:2)
REAL(8):: EF(1:3)
REAL(8):: invJ
phi = (/ self%n1%emData%phi, &
self%n2%emData%phi /)
dPsi = self%dPsi(xi)
invJ = self%invJac(xi, dPsi)
EF(1) = -DOT_PRODUCT(dPsi(1, :), phi)*invJ
EF(2) = 0.D0
EF(3) = 0.D0
END FUNCTION gatherEFSegm
!Get nodes from 1D volume
PURE FUNCTION getNodesSegm(self) RESULT(n)
IMPLICIT NONE
CLASS(meshVol1DCartSegm), INTENT(in):: self
INTEGER, ALLOCATABLE:: n(:)
ALLOCATE(n(1:2))
n = (/ self%n1%n, self%n2%n /)
END FUNCTION getNodesSegm
PURE FUNCTION phy2logSegm(self, r) RESULT(xN)
IMPLICIT NONE
CLASS(meshVol1DCartSegm), INTENT(in):: self
REAL(8), INTENT(in):: r(1:3)
REAL(8):: xN(1:3)
xN = 0.D0
xN(1) = 2.D0*(r(1) - self%x(1))/(self%x(2) - self%x(1)) - 1.D0
END FUNCTION phy2logSegm
!Get next element for a logical position xi
SUBROUTINE nextElementSegm(self, xi, nextElement)
IMPLICIT NONE
CLASS(meshVol1DCartSegm), INTENT(in):: self
REAL(8), INTENT(in):: xi(1:3)
CLASS(*), POINTER, INTENT(out):: nextElement
NULLIFY(nextElement)
IF (xi(1) < -1.D0) THEN
nextElement => self%e2
ELSEIF (xi(1) > 1.D0) THEN
nextElement => self%e1
END IF
END SUBROUTINE nextElementSegm
!Reset the output of nodes in element
PURE SUBROUTINE resetOutputSegm(self)
USE moduleSpecies
USE moduleOutput
IMPLICIT NONE
CLASS(meshVol1DCartSegm), INTENT(inout):: self
INTEGER:: k
DO k = 1, nSpecies
self%n1%output(k)%den = 0.D0
self%n1%output(k)%mom = 0.D0
self%n1%output(k)%tensorS = 0.D0
self%n2%output(k)%den = 0.D0
self%n2%output(k)%mom = 0.D0
self%n2%output(k)%tensorS = 0.D0
END DO
END SUBROUTINE resetOutputSegm
!COMMON FUNCTIONS FOR 1D VOLUME ELEMENTS
!Computes the element Jacobian determinant
PURE FUNCTION detJ1DCart(self, xi, dPsi_in) RESULT(dJ)
IMPLICIT NONE
CLASS(meshVol1DCart), INTENT(in):: self
REAL(8), INTENT(in):: xi(1:3)
REAL(8), INTENT(in), OPTIONAL:: dPsi_in(1:,1:)
REAL(8), ALLOCATABLE:: dPsi(:,:)
REAL(8):: dJ
REAL(8):: dx(1)
IF (PRESENT(dPsi_in)) THEN
dPsi = dPsi_in
ELSE
dPsi = self%dPsi(xi)
END IF
CALL self%partialDer(dPsi, dx)
dJ = dx(1)
END FUNCTION detJ1DCart
!Computes the invers Jacobian
PURE FUNCTION invJ1DCart(self, xi, dPsi_in) RESULT(invJ)
IMPLICIT NONE
CLASS(meshVol1DCart), INTENT(in):: self
REAL(8), INTENT(in):: xi(1:3)
REAL(8), INTENT(in), OPTIONAL:: dPsi_in(1:,1:)
REAL(8), ALLOCATABLE:: dPsi(:,:)
REAL(8):: dx(1)
REAL(8):: invJ
IF (PRESENT(dPsi_in)) THEN
dPsi = dPsi_in
ELSE
dPsi = self%dPsi(xi)
END IF
CALL self%partialDer(dPsi, dx)
invJ = 1.D0/dx(1)
END FUNCTION invJ1DCart
END MODULE moduleMesh1DCart