# error creating composite rotation matrices

I had first posted this question on Math.Stackexchange, but the guys there suggested this was the right place for the problem.

I'm trying to rotate a set of points on a sphere along more than one axis, to get a specific orientation. I wrote code for the same in Fortran and the transformation seems to work well if I rotate the points in any one direction. But as soon as I specify more than one axis of rotation, the solution goes awry. Most of the points, save maybe the extreme ones, go out of the sphere's volume.

My code (pertinent to the question) goes as follows:

DO iSlice = 1, nSlices

IF(iSlice<10) THEN
WRITE(string1,'("slice",i1.1,".dat")'), iSlice
ELSE
WRITE(string1,'("slice",i2.2,".dat")'), iSlice
END IF

!PRINT*,string1
OPEN (1, file = string1)
DO j = 1,4
END DO
x(1:4) = -1.*temp
CLOSE (1)

!Transform the nodal positions as desired
CALL init_Trans
CALL form_translate(-1.*CG)
IF (iRotz) THEN
ang =  (the3*pi/180.0)*(nSlices-iSlice)/(nSlices-1)
r_axis = '-rz'
PRINT*,'angz = ',ang*180./pi
CALL form_rotate(r_axis,ang)
END IF
IF (iRoty) THEN
ang =  (the2*pi/180.0)*(nSlices-iSlice)/(nSlices-1)
r_axis = '-ry'
PRINT*,'angy = ',ang*180./pi
CALL form_rotate(r_axis,ang)
END IF
IF (iRotx) THEN
ang =  (the1*pi/180.0)*(nSlices-iSlice)/(nSlices-1)
r_axis = '-rx'
PRINT*,'angx = ',ang*180./pi
CALL form_rotate(r_axis,ang)
END IF
CALL form_translate(CG)
CALL transform

WRITE(fout,'(A,I2)')'SLICE: ',iSlice
DO i = 1, 4
WRITE(fout,71) xnew(i), ynew(i), znew(i), t(i)
END DO
WRITE(fout,*)''

DO i = 1, 4
WRITE(fout_tec,'(3(D25.17,1X))') xnew(i), ynew(i), znew(i)
END DO

END DO

Where the subroutine definitions are as follows:

SUBROUTINE init_Trans
USE global_param, ONLY: Trans
IMPLICIT NONE

INTEGER :: i,j
! This subroutine initializes the final Transformation matrix as a 4x4 identity matrix
!--------------------------------------------------------------------------------------!
Trans (:,:) = 0
DO i = 1, 4
Trans(i,i) = 1
END DO

END SUBROUTINE init_Trans
! -------------------------------------------------------------------------------------------- !

SUBROUTINE form_translate (D_MOVE)
USE global_param, ONLY: Trans
IMPLICIT NONE

INTERFACE

SUBROUTINE mat_prod(M1, M2, M3)
REAL, DIMENSION(:,:), INTENT(IN) :: M1, M2
REAL, DIMENSION(:,:), INTENT(OUT) :: M3
END SUBROUTINE

END INTERFACE

REAL, DIMENSION(3), INTENT(IN) :: D_MOVE
REAL, DIMENSION(4,4) :: T, Temp

INTEGER :: i, j

! Initialize Translation Matrix
!-------------------------------!
! WRITE(*,*)'FORMULATING TRANSLATION MATRIX...'
DO i = 1, 3
DO j = 1, 3
IF (i .eq. j) THEN
T(i,j) = 1.0;
ELSE
T(i,j) = 0.0;
END IF
END DO
T(i,4) = D_MOVE(i)
END DO
T(4,4) = 1.0;

CALL mat_prod(T,Trans,Temp)
Trans = Temp

END SUBROUTINE form_translate
! -------------------------------------------------------------------------------------------- !

SUBROUTINE form_rotate(r_axis, theta)

USE global_param, ONLY: Trans
IMPLICIT NONE

INTERFACE

SUBROUTINE mat_prod(M1, M2, M3)
REAL, DIMENSION(:,:), INTENT(IN) :: M1, M2
REAL, DIMENSION(:,:), INTENT(OUT) :: M3
END SUBROUTINE

END INTERFACE

REAL, INTENT(IN) :: theta
REAL, DIMENSION(4,4) :: R, Temp

CHARACTER(LEN = 3), INTENT(IN) :: r_axis

INTEGER :: i,j

SELECT CASE (r_axis)

CASE('-rx')
!    WRITE(*,*)'FORMULATING X-ROTATION MATRIX...'
! Initialize x-Rotation matrix
!----------------------------!
DO i = 2,3
DO j = 2, 3
IF (i .eq. j) THEN
R(i,j) = cos(theta)
ELSE
R(i,j) = ((-1)**(i-1))*sin(theta)
END IF
END DO
END DO

DO i = 1, 4, 3
DO j = 1, 4, 3
IF (i .eq. j) R(i,j) = 1.0
END DO
END DO

CASE('-ry')
!    WRITE(*,*)'FORMULATING Y-ROTATION MATRIX...'
! Initialize y-Rotation matrix
!----------------------------!
DO i = 1,3,2
R(i,i) = cos(theta)
IF (mod(i+1,4) .eq. 0) THEN
R(i,4-i) = -sin(theta)
ELSE
R(i,4-i) = sin(theta)
END IF
END DO

DO i = 2, 4, 2
R(i,i) = 1.0
END DO

CASE('-rz')
!    WRITE(*,*)'FORMULATING Z-ROTATION MATRIX...'
! Initialize z-Rotation matrix
!----------------------------!
DO i = 1,2
DO j = 1, 2
IF (i .eq. j) THEN
R(i,j) = cos(theta)
ELSE
R(i,j) = ((-1)**i)*sin(theta)
END IF
END DO
END DO

DO i = 3, 4
DO j = 3, 4
IF (i .eq. j) R(i,j) = 1.0
END DO
END DO

END SELECT

CALL mat_prod(R,Trans,Temp)
Trans = Temp
DO i = 1, 4
PRINT*,Trans(i,:)
END DO
END SUBROUTINE form_rotate
! -------------------------------------------------------------------------------------------- !

SUBROUTINE transform
! Transform coordinates of each point using p_new = Tran*p
!----------------------------------------------------------!
USE global_param
IMPLICIT NONE

INTERFACE

SUBROUTINE mat_prod(M1, M2, M3)
REAL, DIMENSION(:,:), INTENT(IN) :: M1, M2
REAL, DIMENSION(:,:), INTENT(OUT) :: M3
END SUBROUTINE

END INTERFACE

REAL, DIMENSION(4,1) :: p, p_new
INTEGER :: i,j

p(4,1) = 1.0
DO i = 1, n_nodes
p(1,1) = x(i); p(2,1) = y(i); p(3,1) = z(i)
CALL mat_prod(Trans, p, p_new)
xnew(i) = p_new(1,1); ynew(i) = p_new(2,1); znew(i) = p_new(3,1)
END DO

END SUBROUTINE transform

I have tried creating a composite rotation matrix so that the resulting rotation, along both the axes, may be handled at once. And I guess this is where I'm going wrong, as the code works well for rotating points about individual axes. Could anyone help me figure out the problem?

Thanks a ton!

-
What's mat_prod ? A roll-your-own replacement for matmul ? –  High Performance Mark Oct 8 '13 at 11:04
en.wikipedia.org/wiki/Rotation_matrix see axis angle formula –  george Oct 8 '13 at 11:49
In case your problems persist, you could try quaternions. –  Stefan Oct 8 '13 at 12:48
more you may find useful seeing as you are working with 4x4 transformation matrices euclideanspace.com/maths/geometry/affine/matrix4x4/index.htm. I might advise working through the 3x3 form first and adding the translation later if you are really stuck. –  george Oct 8 '13 at 15:04
@Stefan, quaternions are useful if you're doing lots of rotation concatenation, but that shouldn't be a problem in a single concatenation. –  Mark Ping Oct 8 '13 at 15:33