define_bc_segmented_s_line_round.f90

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!              DEFINE_BC_SEGMENTED_S_LINE_ROUND   Jan. 2014                    |
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subroutine define_bc_segmented_s_line_round(params,osolve,vo,bcdef)

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!((((((((((((((((  Purpose of the routine  )))))))))))))))))))))))))))))))))))))
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! This routine assigns the velocity boundary conditions for the rounded
! segmented s-line geometry

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!((((((((((((((((  declaration of the subroutine arguments  ))))))))))))))))))))
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use definitions
!use mpi

implicit none

include 'mpif.h'

type (parameters) params
type (octreesolve) osolve
type (void) vo
type (bc_definition) bcdef

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!(((((((((((((((( declaration of the subroutine internal variables )))))))))))))
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integer i,iproc,nproc,ierr
double precision :: eps,pi,x1,x2,phi,yend,xstart,ystart
double precision :: theta,l,vin,vzfluxscl,cntvel,dxy,xend,xsym,ymax,xwidth
double precision :: ywidth,nb,uextra,vextra,arcradius,ystartarc
double precision :: yendarc
double precision,dimension(:),allocatable :: x0,ldisp
integer nelemx,nelemz,xdisp,ydisp

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call mpi_comm_size (mpi_comm_world,nproc,ierr)
call mpi_comm_rank (mpi_comm_world,iproc,ierr)

eps=1.d-10
osolve%kfix=0
osolve%kfixt=0
pi=atan(1.d0)*4.d0

l=bcdef%bc_parameters(1)
phi=bcdef%bc_parameters(2)
theta=bcdef%bc_parameters(3)
xsym=bcdef%bc_parameters(4)
ystart=bcdef%bc_parameters(5)
yend=bcdef%bc_parameters(6)
ymax=bcdef%bc_parameters(7)
vin=bcdef%bc_parameters(8)
nelemx=idint(bcdef%bc_parameters(9))
nelemz=idint(bcdef%bc_parameters(10))
uextra=bcdef%bc_parameters(11)
vextra=bcdef%bc_parameters(12)
arcradius=bcdef%bc_parameters(13)

ywidth=yend-ystart
phi=phi/180.d0*pi
theta=theta/180.d0*pi
xwidth=ywidth*tan(theta)
xstart=xsym-(xwidth/2.d0)
xend=xsym+(xwidth/2.d0)
vzfluxscl=0.5d0*(1.d0+(tan(phi)/tan((pi-phi)/2.d0)))
nb=2**params%levelmax_oct
dxy=1.d0/2**(params%levelmax_oct+1.d0)
ystartarc=ystart-arcradius*tan(theta/2.d0)                                      ! Define the y-start of the arcuate region
yendarc=ystart+arcradius*tan(theta/2.d0)*cos(theta)                             ! Define the y-end of the arcuate region

allocate(x0(osolve%nnode))
do i=1,osolve%nnode
  if (osolve%y(i).le.ystartarc) then
    x0(i)=xstart
  else if (osolve%y(i).le.yendarc) then
    x0(i)=xstart+arcradius-sqrt(arcradius**2.d0-(osolve%y(i)-ystartarc)**2.d0)
  else if (osolve%y(i).le.yend) then
    x0(i)=xstart+(osolve%y(i)-ystart)*tan(theta)
  else
    x0(i)=xend
  endif
enddo

! write(*,*) 'arcradius: ',arcradius
! write(*,*) 'ystart: ',ystart
! write(*,*) 'ystartarc: ',ystartarc
! write(*,*) 'yendarc: ',yendarc
! write(*,*) 'x0: ',x0(:)

if (params%isobc) then
  allocate (ldisp(osolve%nnode))
  do i=1,osolve%nnode
    xdisp=idnint(x0(i)*nb)+1
    ydisp=idnint(osolve%y(i)*nb)+1
    ldisp(i)=l+bcdef%zisodisp(xdisp,ydisp)
  enddo
endif

do i=1,osolve%nnode
  cntvel=0.d0
  if (params%isobc) l=ldisp(i)
  x1=x0(i)-l/tan(phi)
  x2=x0(i)+l/tan(phi)
  if (((x2-x0(i))-(x0(i)-x1)).gt.eps) vzfluxscl=1.d0                            ! Set vzfluxscl equal to one if B/Cs are not symmetric
  if (osolve%x(i).lt.eps) then
    osolve%kfix((i-1)*3+1)=1 ; osolve%u(i)=0.d0
    osolve%kfix((i-1)*3+2)=1 ; osolve%v(i)=0.d0
    osolve%kfix((i-1)*3+3)=1 ; osolve%w(i)=0.d0
    if (osolve%y(i).le.(ymax-(real(nelemx)*dxy))) then
      osolve%u(i)=1.d0+uextra
    elseif (osolve%y(i).le.(ymax+(real(nelemx)*dxy))) then
      osolve%u(i)=(1.d0+uextra)*(1.d0-(osolve%y(i)-(ymax-(real(nelemx)*dxy)))/(2.d0*real(nelemx)*dxy))
    endif
  endif
  if (osolve%x(i).gt.1.d0-eps) then
    osolve%kfix((i-1)*3+1)=1 ; osolve%u(i)=0.d0
    !osolve%kfix((i-1)*3+2)=1 ; osolve%v(i)=0.d0
    !osolve%kfix((i-1)*3+3)=1 ; osolve%w(i)=0.d0
  endif
  if (osolve%y(i).lt.eps) then
    !osolve%kfix((i-1)*3+1)=1 ; osolve%u(i)=0.d0
    osolve%kfix((i-1)*3+2)=1 ; osolve%v(i)=0.d0
    !osolve%kfix((i-1)*3+3)=1 ; osolve%w(i)=0.d0
  endif
  if (osolve%y(i).gt.1.d0-eps) then
    !osolve%kfix((i-1)*3+1)=1 ; osolve%u(i)=0.d0
    osolve%kfix((i-1)*3+2)=1 ; osolve%v(i)=0.d0
    !osolve%kfix((i-1)*3+3)=1 ; osolve%w(i)=0.d0
  endif
  if (osolve%z(i).lt.eps) then
    osolve%kfix((i-1)*3+1)=1 ; osolve%u(i)=0.d0
    osolve%kfix((i-1)*3+2)=1 ; osolve%v(i)=0.d0
    osolve%kfix((i-1)*3+3)=1 ; osolve%w(i)=0.d0
    if (osolve%x(i).le.(x1-real(nelemz)*dxy)) then
      if (osolve%y(i).le.(ymax-(real(nelemx)*dxy))) then
        osolve%u(i)=1.d0+uextra
      elseif (osolve%y(i).le.(ymax+(real(nelemx)*dxy))) then
        osolve%u(i)=(1.d0+uextra)*(1.d0-(osolve%y(i)-(ymax-(real(nelemx)*dxy)))/(2.d0*real(nelemx)*dxy))
      endif
    elseif (osolve%x(i).le.(x1+real(nelemz)*dxy)) then
      if (osolve%y(i).le.(ymax-(real(nelemx)*dxy))) then
        osolve%u(i)=1.d0+uextra
      elseif (osolve%y(i).le.(ymax+(real(nelemx)*dxy))) then
        osolve%u(i)=(1.d0+uextra)*(1.d0-(osolve%y(i)-(ymax-(real(nelemx)*dxy)))/(2.d0*real(nelemx)*dxy))
      endif
      osolve%w(i)=(osolve%u(i)/(1.d0+uextra))*(osolve%x(i)-(x1-(real(nelemz)*dxy)))/(2.d0*real(nelemz)*dxy)*(vzfluxscl*(-sin(phi)))
      osolve%u(i)=osolve%u(i)*(((1.d0-(osolve%x(i)-(x1-(real(nelemz)*dxy)))/(2.d0*real(nelemz)*dxy))*(1.d0-vzfluxscl*cos(phi)))+vzfluxscl*cos(phi))
    elseif (osolve%x(i).le.(x2-real(nelemz)*dxy)) then
      if (osolve%y(i).le.(ymax-(real(nelemx)*dxy))) then
        osolve%u(i)=1.d0+uextra
      elseif (osolve%y(i).le.(ymax+(real(nelemx)*dxy))) then
        osolve%u(i)=(1.d0+uextra)*(1.d0-(osolve%y(i)-(ymax-(real(nelemx)*dxy)))/(2.d0*real(nelemx)*dxy))
      endif
      osolve%w(i)=(osolve%u(i)/(1.d0+uextra))*vzfluxscl*(-sin(phi))
      osolve%u(i)=osolve%u(i)*vzfluxscl*cos(phi)
    elseif (osolve%x(i).le.(x2+real(nelemz)*dxy)) then
      if (osolve%y(i).le.(ymax-(real(nelemx)*dxy))) then
        osolve%u(i)=1.d0+uextra
      elseif (osolve%y(i).le.(ymax+(real(nelemx)*dxy))) then
        osolve%u(i)=(1.d0+uextra)*(1.d0-(osolve%y(i)-(ymax-(real(nelemx)*dxy)))/(2.d0*real(nelemx)*dxy))
      endif
      osolve%w(i)=(osolve%u(i)/(1.d0+uextra))*((1.d0-(osolve%x(i)-(x2-(real(nelemz)*dxy)))/(2.d0*real(nelemz)*dxy))*(vzfluxscl*(-sin(phi))))
      osolve%u(i)=osolve%u(i)*((1.d0-(osolve%x(i)-(x2-(real(nelemz)*dxy)))/(2.d0*real(nelemz)*dxy))*(vzfluxscl*cos(phi)))
    endif
    osolve%kfixt(i)=1
    osolve%temp(i)=1.d0
  endif
  if (osolve%z(i).gt.1.d0-eps) then
    osolve%kfix((i-1)*3+1)=1 ; osolve%u(i)=0.d0
    osolve%kfix((i-1)*3+2)=1 ; osolve%v(i)=0.d0
    osolve%kfix((i-1)*3+3)=1 ; osolve%w(i)=0.d0
    osolve%kfixt(i)=1
    osolve%temp(i)=0.d0
  endif
  if (.not.vo%influid(i)) then
    osolve%kfixt(i)=1
    osolve%temp(i)=0.d0
  endif
  if (abs(bcdef%utrans).gt.eps) then
    osolve%u(i)=osolve%u(i)+bcdef%utrans
  endif
  if (abs(bcdef%vtrans).gt.eps) then
    osolve%v(i)=osolve%v(i)+bcdef%vtrans
  endif
  osolve%u(i)=osolve%u(i)*vin
  osolve%v(i)=osolve%v(i)*vin
  osolve%w(i)=osolve%w(i)*vin
enddo

if (params%isobc) then
  call define_isostasy_bc(params,osolve,bcdef)
  deallocate(ldisp)
endif
deallocate(x0)

end
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