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qssh.f
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subroutine qssh(y,k,lup,llw)
implicit none
c
c calculation of response to sh source
c y(6,6): solution vector (complex)
c k: wave number
c
integer lup,llw
double precision k
double complex y(6,6)
c
include 'qsglobal.h'
c
c work space
c
integer i,istp,l,n,key
double complex cnorm
double complex y0(2),b(2,6),b0(2,6)
double complex y1(2),yup(2),ylw(2)
double complex hk(2,2,nzmax),coef(2,2),cinc(6),c0
logical rsite
c
c===============================================================================
c
c matrix propagation from surface to source
c
rsite=.false.
do l=lup,ls-1
n=nno(l)
call qshksh(hk(1,1,l),hp(l),n,rsite)
enddo
do l=ls,llw-1
n=nno(l)
call qshksh(hk(1,1,l),-hp(l),n,rsite)
enddo
c
c yup: the starting solution vector
c
yup(1)=(1.d0,0.d0)
if(lup.eq.1.and.isurf.eq.0)then
yup(2)=(0.d0,0.d0)
else
n=nno(lup)
yup(2)=cmu(n)*ks(n)
endif
if(lup.eq.lzr)call cmemcpy(yup,y0,2)
c
do l=lup+1,ls
n=nno(l-1)
c
c determination of propagation matrix
c
call caxcb(hk(1,1,l-1),yup,2,2,1,y1)
call cmemcpy(y1,yup,2)
c
c normalization
c
if(l.gt.lzr)then
cnorm=cdexp(-ks(n)*dcmplx(hp(l-1),0.d0))
y0(1)=y0(1)*cnorm
y0(2)=y0(2)*cnorm
else if(l.eq.lzr)then
call cmemcpy(yup,y0,2)
endif
enddo
c
c===============================================================================
c
c matrix propagation from half-space to source
c
c ylw: the starting solution vector
c
n=nno(llw)
ylw(1)=(1.d0,0.d0)
if(sh(llw))then
ylw(2)=-cmu(n)*ks(n)
else
ylw(2)=(0.d0,0.d0)
endif
if(llw.gt.ls.and.llw.eq.lzr)call cmemcpy(ylw,y0,2)
c
do l=llw-1,ls,-1
n=nno(l)
c
c determination of propagation matrix
c
call caxcb(hk(1,1,l),ylw,2,2,1,y1)
call cmemcpy(y1,ylw,2)
if(l.lt.lzr)then
cnorm=cdexp(-ks(n)*dcmplx(hp(l),0.d0))
y0(1)=y0(1)*cnorm
y0(2)=y0(2)*cnorm
else if(l.gt.ls.and.l.eq.lzr)then
call cmemcpy(ylw,y0,2)
endif
enddo
c
c===============================================================================
c source function
c===============================================================================
c
do istp=1,6
do i=1,2
c b(i,istp)=dcmplx(sfct0(i+4,istp)+k*sfct1(i+4,istp),0.d0)
b(i,istp)=sfct0(i+4,istp)+dcmplx(k,0.d0)*sfct1(i+4,istp)
enddo
enddo
do i=1,2
coef(i,1)=yup(i)
coef(i,2)=-ylw(i)
enddo
if(ipath.eq.1)call cmemcpy(b,b0,12)
key=0
call cdgemp(coef,b,2,6,0.d0,key)
if(key.eq.0)then
print *,'warning in qssh: anormal exit from cdgemp!'
return
endif
if(lzr.le.ls)then
do istp=1,6
do i=1,2
y(i+4,istp)=b(1,istp)*y0(i)
enddo
enddo
else
do istp=1,6
do i=1,2
y(i+4,istp)=b(2,istp)*y0(i)
enddo
enddo
endif
if(ipath.eq.1)then
n=nno(lpath)
ylw(1)=(1.d0,0.d0)
if(sh(lpath))then
ylw(2)=-cmu(n)*ks(n)
else
ylw(2)=(0.d0,0.d0)
endif
if(lpath.gt.ls.and.lpath.eq.lzr)call cmemcpy(ylw,y0,2)
do l=lpath-1,ls,-1
n=nno(l)
c
c determination of propagation matrix
c
call caxcb(hk(1,1,l),ylw,2,2,1,y1)
call cmemcpy(y1,ylw,2)
c
if(l.lt.lzr)then
cnorm=cdexp(-ks(n)*dcmplx(hp(l),0.d0))
y0(1)=y0(1)*cnorm
y0(2)=y0(2)*cnorm
else if(l.gt.ls.and.l.eq.lzr)then
call cmemcpy(ylw,y0,2)
endif
enddo
do i=1,2
coef(i,1)=yup(i)
coef(i,2)=-ylw(i)
enddo
key=0
call cdgemp(coef,b0,2,6,0.d0,key)
if(key.eq.0)then
print *,'warning in qssh: anormal exit from cdgemp!'
return
endif
if(lzr.le.ls)then
do istp=1,6
do i=1,2
y(i+4,istp)=y(i+4,istp)-b0(1,istp)*y0(i)
enddo
enddo
else
do istp=1,6
do i=1,2
y(i+4,istp)=y(i+4,istp)-b0(2,istp)*y0(i)
enddo
enddo
endif
endif
c
if(n0rs.gt.0)then
c
c for receiver-site structure different from source-site structure
c
n=nno(lzr)
do istp=1,6
cinc(istp)=(0.5d0,0.d0)*(y(5,istp)+y(6,istp)/(cmu(n)*ks(n)))
enddo
rsite=.true.
do l=1,lprs-1
n=nnors(l)
call qshksh(hk(1,1,l),hprs(l),n,rsite)
enddo
c
c yup: the starting solution vector
c
yup(1)=(1.d0,0.d0)
if(isurf.eq.0)then
yup(2)=(0.d0,0.d0)
else
yup(2)=cmurs(1)*ksrs(1)
endif
if(lzrrs.eq.1)call cmemcpy(yup,y0,2)
c
do l=2,lprs
n=nnors(l-1)
c
c determination of propagation matrix
c
call caxcb(hk(1,1,l-1),yup,2,2,1,y1)
call cmemcpy(y1,yup,2)
c
c normalization
c
if(l.gt.lzrrs)then
cnorm=cdexp(-ksrs(n)*dcmplx(hprs(l-1),0.d0))
y0(1)=y0(1)*cnorm
y0(2)=y0(2)*cnorm
else if(l.eq.lzrrs)then
call cmemcpy(yup,y0,2)
endif
enddo
n=nnors(lprs)
c0=(0.5d0,0.d0)*(yup(1)+yup(2)/(cmurs(n)*ksrs(n)))
do istp=1,6
y(5,istp)=y0(1)*cinc(istp)/c0
y(6,istp)=y0(2)*cinc(istp)/c0
enddo
endif
if(isurf.eq.2)then
c
c free surface corrections
c
do istp=1,6
y(5,istp)=(2.d0,0.d0)*y(5,istp)
y(6,istp)=(0.d0,0.d0)
enddo
endif
return
end