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#include "cctk.h"
#include "cctk_Arguments.h"
#include "cctk_Functions.h"
#include "cctk_Parameters.h"
module qlm_killing_transportation
use cctk
use constants
use ricci2
use tensor2
implicit none
DECLARE_CCTK_FUNCTIONS
DECLARE_CCTK_PARAMETERS
private
public transport_along_equator
public transport_along_meridians
contains
subroutine transport_along_equator (CCTK_ARGUMENTS, hn, i0, xi, chi)
DECLARE_CCTK_ARGUMENTS
integer, intent(in) :: hn
integer, intent(in) :: i0
CCTK_REAL, intent(inout) :: xi(2), chi
integer :: j0
integer :: nsteps
j0 = 1+qlm_nghostsphi(hn)
nsteps = qlm_nphi(hn) - 2*qlm_nghostsphi(hn)
call transport (CCTK_PASS_FTOF, hn, i0, j0, 0, 1, nsteps, xi, chi)
end subroutine transport_along_equator
subroutine transport_along_meridians (CCTK_ARGUMENTS, hn, i0)
DECLARE_CCTK_ARGUMENTS
integer, intent(in) :: hn
integer, intent(in) :: i0
CCTK_REAL :: xi(2), chi
integer :: j0
integer :: dir
integer :: nsteps
do j0 = 1+qlm_nghostsphi(hn), qlm_nphi(hn)-qlm_nghostsphi(hn)
do dir=-1,+1,2
if (dir==-1) nsteps = i0 - (1+qlm_nghoststheta(hn))
if (dir==+1) nsteps = (qlm_ntheta(hn)-qlm_nghoststheta(hn)) - i0
xi(1) = qlm_xi_t(i0,j0,hn)
xi(2) = qlm_xi_p(i0,j0,hn)
chi = qlm_chi(i0,j0,hn)
call transport (CCTK_PASS_FTOF, hn, i0, j0, dir, 0, nsteps, xi, chi)
end do
end do
end subroutine transport_along_meridians
subroutine transport (CCTK_ARGUMENTS, hn, i0, j0, di, dj, nsteps, xi, chi)
DECLARE_CCTK_ARGUMENTS
integer, intent(in) :: hn
integer, intent(in) :: i0, j0
integer, intent(in) :: di, dj
integer, intent(in) :: nsteps
CCTK_REAL,intent(inout) :: xi(2), chi
CCTK_REAL :: vv(2)
CCTK_REAL :: xi_dot(2), chi_dot
CCTK_REAL :: xi1(2), chi1
CCTK_REAL :: xi1_dot(2), chi1_dot
integer :: n
integer :: i, j
i = i0
j = j0
vv(1) = di * qlm_delta_theta(hn)
vv(2) = dj * qlm_delta_phi(hn)
do n=1,nsteps
call transport_rhs (CCTK_PASS_FTOF, hn, i, j, xi, chi, vv, xi_dot, chi_dot)
xi1 = xi + xi_dot
chi1 = chi + chi_dot
i = i + di
j = j + dj
if (j < 1+qlm_nghostsphi(hn)) j = j + (qlm_nphi(hn)-2*qlm_nghostsphi(hn))
if (j > qlm_nphi(hn)-qlm_nghostsphi(hn)) j = j - (qlm_nphi(hn)-2*qlm_nghostsphi(hn))
call transport_rhs &
(CCTK_PASS_FTOF, hn, i, j, xi1, chi1, vv, xi1_dot, chi1_dot)
xi = xi + 0.5d0 * (xi_dot + xi1_dot)
chi = chi + 0.5d0 * (chi_dot + chi1_dot)
qlm_xi_t(i,j,hn) = xi(1)
qlm_xi_p(i,j,hn) = xi(2)
qlm_chi(i,j,hn) = chi
end do
end subroutine transport
subroutine transport_rhs (CCTK_ARGUMENTS, hn, i, j, xi, chi, vv, xi_dot, chi_dot)
DECLARE_CCTK_ARGUMENTS
integer, intent(in) :: hn
integer, intent(in) :: i, j
CCTK_REAL, intent(in) :: xi(2), chi
CCTK_REAL, intent(in) :: vv(2)
CCTK_REAL, intent(out) :: xi_dot(2), chi_dot
CCTK_REAL :: qq(2,2), dqq(2,2,2), dtq, qu(2,2), gamma(2,2,2), rsc
if (i<1+qlm_nghoststheta(hn) .or. i>qlm_ntheta(hn)-qlm_nghoststheta(hn) &
.or. j<1+qlm_nghostsphi(hn) .or. j>qlm_nphi(hn)-qlm_nghostsphi(hn)) then
call CCTK_WARN (0, "internal error")
end if
if (i-1<1 .or. i+1>qlm_ntheta(hn) .or. j-1<1 .or. j+1>qlm_nphi(hn)) then
call CCTK_WARN (0, "internal error")
end if
qq(1,1) = qlm_qtt(i,j,hn)
qq(1,2) = qlm_qtp(i,j,hn)
qq(2,2) = qlm_qpp(i,j,hn)
qq(2,1) = qq(1,2)
dqq(1,1,1) = qlm_dqttt(i,j,hn)
dqq(1,2,1) = qlm_dqtpt(i,j,hn)
dqq(2,2,1) = qlm_dqppt(i,j,hn)
dqq(1,1,2) = qlm_dqttp(i,j,hn)
dqq(1,2,2) = qlm_dqtpp(i,j,hn)
dqq(2,2,2) = qlm_dqppp(i,j,hn)
dqq(2,1,:) = dqq(1,2,:)
rsc = qlm_rsc(i,j,hn)
call calc_2det (qq, dtq)
call calc_2inv (qq, dtq, qu)
call calc_2connections (qu, dqq, gamma)
call killing_transport_rhs &
(xi, chi, qq, dtq, qu, gamma, rsc, vv, xi_dot, chi_dot)
end subroutine transport_rhs
subroutine killing_transport_rhs &
(xi, chi, qq, dtq, qu, gamma2, rsc2, vv, xi_dot, chi_dot)
CCTK_REAL, intent(in) :: xi(2), chi
CCTK_REAL, intent(in) :: qq(2,2), dtq, qu(2,2), gamma2(2,2,2), rsc2
CCTK_REAL, intent(in) :: vv(2)
CCTK_REAL, intent(out) :: xi_dot(2), chi_dot
integer :: i, k, l
! Wald eqn (C.3.6):
! D_k D_j xi^i = R^i_jkl xi^l
! define:
! L^i_j = D_j x^i
! then: see Wald eqns (C.3.7) and (C.3.8):
! v^k D_k xi^i = L^i_k v^k
! v^k D_k L^i_j = R^i_jkl v^k xi^l
! in 2D we have:
! R_ijkl = 1/2 q R epsilon2_ij epsilon2_kl
! L_ij = epsilon2_ij sqrt(q) chi
! then:
! v^k D_k xi^i = epsilon2^i_k sqrt(q) chi v^k
! v^k D_k epsilon2^i_j sqrt(q) chi = R^i_jkl v^k xi^l
! v^k D_k chi = 1/2 sqrt(q) R epsilon2_kl v^k xi^l
! define:
! X_dot = v^i d/dx^i X (partial derivatives)
do i=1,2
xi_dot(i) = 0
do k=1,2
do l=1,2
xi_dot(i) = xi_dot(i) &
+ qu(i,l) * epsilon2(l,k) * sqrt(dtq) * chi * vv(k) &
- vv(k) * gamma2(i,l,k) * xi(l)
end do
end do
end do
chi_dot = 0
do k=1,2
do l=1,2
chi_dot = chi_dot &
+ 0.5d0 * sqrt(dtq) * rsc2 * epsilon2(k,l) * vv(k) * xi(l)
end do
end do
end subroutine killing_transport_rhs
#if 0
subroutine killing_equation (qq, qu, xi, gxi, zeta, trzeta, zetasq)
CCTK_REAL, intent(in) :: qq(2,2), qu(2,2)
CCTK_REAL, intent(in) :: xi(2), gxi(2,2)
CCTK_REAL, intent(out) :: zeta(2,2), trzeta, zetasq
integer :: i, j, k, l
do i=1,2
do j=1,2
! zeta_ij = D_i xi_j + D_j xi_i
zeta(i,j) = 0
do k=1,2
do l=1,2
zeta(i,j) = zeta(i,j) + qq(j,k) * gxi(k,i) + qq(i,k) * gxi(k,j)
end do
end do
end do
end do
trzeta = 0
do i=1,2
do j=1,2
trzeta = trzeta + qu(i,j) * zeta(i,j)
end do
end do
zetasq = 0
do i=1,2
do j=1,2
do k=1,2
do l=1,2
zetasq = zetasq + qu(i,k) * qu(j,l) * zeta(i,j) * zeta(k,l)
end do
end do
end do
end do
end subroutine killing_equation
#endif
end module qlm_killing_transportation
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