ISCE_INSAR/components/isceobj/Util/src/radar_to_xyz.F

c****************************************************************

	subroutine radar_to_xyz(elp,peg,ptm,height)

c****************************************************************
c**
c**	FILE NAME: radar_to_xyz.for
c**
c**     DATE WRITTEN:1/15/93 
c**
c**     PROGRAMMER:Scott Hensley
c**
c** 	FUNCTIONAL DESCRIPTION:This routine computes the transformation
c**     matrix and translation vector needed to get between radar (s,c,h)
c**     coordinates and (x,y,z) WGS-84 coordinates.
c**
c**     ROUTINES CALLED:euler,
c**  
c**     NOTES: none
c**
c**     UPDATE LOG:
c**
c*****************************************************************

       	implicit none

c	INPUT VARIABLES:

	type ellipsoid
           sequence
	   real (8) r_a        
	   real (8) r_e2
	end type ellipsoid
	type (ellipsoid) elp

	type pegtype
           sequence
	   real (8) r_lat
	   real (8) r_lon
	   real (8) r_hdg
	end type pegtype
	type (pegtype) peg
   
        real*8, intent(in), optional :: height
        
c   	OUTPUT VARIABLES:

	type pegtrans
          sequence
	  real (8) r_mat(3,3)
	  real (8) r_matinv(3,3)
	  real (8) r_ov(3)
	  real (8) r_radcur
        end type pegtrans
	type (pegtrans) ptm

c	LOCAL VARIABLES:
        integer i,j,i_type
        real*8 r_llh(3),r_p(3),r_slt,r_clt,r_clo,r_slo,r_up(3)
        real*8 r_chg,r_shg,rdir
        real*8 r_height

c	DATA STATEMENTS:none

C	FUNCTION STATEMENTS:
        external rdir

c  	PROCESSING STEPS:

c Check if the height is given

      if (present(height)) then
          r_height = height
      else
          r_height = 0.0d0
      endif

c       first determine the rotation matrix

        
        r_clt = cos(peg%r_lat)
        r_slt = sin(peg%r_lat)
        r_clo = cos(peg%r_lon)
        r_slo = sin(peg%r_lon)
        r_chg = cos(peg%r_hdg)
        r_shg = sin(peg%r_hdg)

	ptm%r_mat(1,1) = r_clt*r_clo
	ptm%r_mat(1,2) = -r_shg*r_slo - r_slt*r_clo*r_chg
	ptm%r_mat(1,3) = r_slo*r_chg - r_slt*r_clo*r_shg
	ptm%r_mat(2,1) = r_clt*r_slo 
	ptm%r_mat(2,2) = r_clo*r_shg - r_slt*r_slo*r_chg 
	ptm%r_mat(2,3) = -r_clo*r_chg - r_slt*r_slo*r_shg
	ptm%r_mat(3,1) = r_slt
	ptm%r_mat(3,2) = r_clt*r_chg
	ptm%r_mat(3,3) = r_clt*r_shg

	do i=1,3
	   do j=1,3
	      ptm%r_matinv(i,j) = ptm%r_mat(j,i)
	   enddo
	enddo

c       find the translation vector

        ptm%r_radcur = rdir(elp%r_a,elp%r_e2,peg%r_hdg,peg%r_lat) + r_height

        i_type = 1
	r_llh(1) = peg%r_lat
	r_llh(2) = peg%r_lon
	r_llh(3) = r_height
        call latlon(elp,r_p,r_llh,i_type)

        r_clt = cos(peg%r_lat)
        r_slt = sin(peg%r_lat)
        r_clo = cos(peg%r_lon)
        r_slo = sin(peg%r_lon)
        r_up(1) = r_clt*r_clo        
        r_up(2) = r_clt*r_slo
        r_up(3) = r_slt        

        do i=1,3
	   ptm%r_ov(i) = r_p(i) - ptm%r_radcur*r_up(i)
	enddo

        end
Adding all files 2019-01-16 19:40:08 +00:00			`c****************************************************************`

			`subroutine radar_to_xyz(elp,peg,ptm,height)`

			`c****************************************************************`
			`c**`
			`c** FILE NAME: radar_to_xyz.for`
			`c**`
			`c** DATE WRITTEN:1/15/93`
			`c**`
			`c** PROGRAMMER:Scott Hensley`
			`c**`
			`c** FUNCTIONAL DESCRIPTION:This routine computes the transformation`
			`c** matrix and translation vector needed to get between radar (s,c,h)`
			`c** coordinates and (x,y,z) WGS-84 coordinates.`
			`c**`
			`c** ROUTINES CALLED:euler,`
			`c**`
			`c** NOTES: none`
			`c**`
			`c** UPDATE LOG:`
			`c**`
			`c*****************************************************************`

			`implicit none`

			`c INPUT VARIABLES:`

			`type ellipsoid`
			`sequence`
			`real (8) r_a`
			`real (8) r_e2`
			`end type ellipsoid`
			`type (ellipsoid) elp`

			`type pegtype`
			`sequence`
			`real (8) r_lat`
			`real (8) r_lon`
			`real (8) r_hdg`
			`end type pegtype`
			`type (pegtype) peg`

			`real*8, intent(in), optional :: height`

			`c OUTPUT VARIABLES:`

			`type pegtrans`
			`sequence`
			`real (8) r_mat(3,3)`
			`real (8) r_matinv(3,3)`
			`real (8) r_ov(3)`
			`real (8) r_radcur`
			`end type pegtrans`
			`type (pegtrans) ptm`

			`c LOCAL VARIABLES:`
			`integer i,j,i_type`
			`real*8 r_llh(3),r_p(3),r_slt,r_clt,r_clo,r_slo,r_up(3)`
			`real*8 r_chg,r_shg,rdir`
			`real*8 r_height`

			`c DATA STATEMENTS:none`

			`C FUNCTION STATEMENTS:`
			`external rdir`

			`c PROCESSING STEPS:`

			`c Check if the height is given`

			`if (present(height)) then`
			`r_height = height`
			`else`
			`r_height = 0.0d0`
			`endif`

			`c first determine the rotation matrix`


			`r_clt = cos(peg%r_lat)`
			`r_slt = sin(peg%r_lat)`
			`r_clo = cos(peg%r_lon)`
			`r_slo = sin(peg%r_lon)`
			`r_chg = cos(peg%r_hdg)`
			`r_shg = sin(peg%r_hdg)`

			`ptm%r_mat(1,1) = r_clt*r_clo`
			`ptm%r_mat(1,2) = -r_shgr_slo - r_sltr_clo*r_chg`
			`ptm%r_mat(1,3) = r_slor_chg - r_sltr_clo*r_shg`
			`ptm%r_mat(2,1) = r_clt*r_slo`
			`ptm%r_mat(2,2) = r_clor_shg - r_sltr_slo*r_chg`
			`ptm%r_mat(2,3) = -r_clor_chg - r_sltr_slo*r_shg`
			`ptm%r_mat(3,1) = r_slt`
			`ptm%r_mat(3,2) = r_clt*r_chg`
			`ptm%r_mat(3,3) = r_clt*r_shg`

			`do i=1,3`
			`do j=1,3`
			`ptm%r_matinv(i,j) = ptm%r_mat(j,i)`
			`enddo`
			`enddo`

			`c find the translation vector`

			`ptm%r_radcur = rdir(elp%r_a,elp%r_e2,peg%r_hdg,peg%r_lat) + r_height`

			`i_type = 1`
			`r_llh(1) = peg%r_lat`
			`r_llh(2) = peg%r_lon`
			`r_llh(3) = r_height`
			`call latlon(elp,r_p,r_llh,i_type)`

			`r_clt = cos(peg%r_lat)`
			`r_slt = sin(peg%r_lat)`
			`r_clo = cos(peg%r_lon)`
			`r_slo = sin(peg%r_lon)`
			`r_up(1) = r_clt*r_clo`
			`r_up(2) = r_clt*r_slo`
			`r_up(3) = r_slt`

			`do i=1,3`
			`ptm%r_ov(i) = r_p(i) - ptm%r_radcur*r_up(i)`
			`enddo`

			`end`