coordinate_routines.f90

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MODULE coordinate_routines

  USE base_routines
  USE constants
  USE input_output
  USE iso_varying_string
  USE kinds
  USE maths
  USE strings
  USE types
  
#include "macros.h"

  IMPLICIT NONE

!!TODO: Should all of the get/set/create/destroy routines be accessed via pointers???

  PRIVATE

  !Module parameters

  INTEGER(INTG), PARAMETER :: coordinate_rectangular_cartesian_type=1
  INTEGER(INTG), PARAMETER :: coordinate_cylindrical_polar_type=2
  INTEGER(INTG), PARAMETER :: coordinate_spherical_polar_type=3
  INTEGER(INTG), PARAMETER :: coordinate_prolate_spheroidal_type=4
  INTEGER(INTG), PARAMETER :: coordinate_oblate_spheroidal_type=5

  INTEGER(INTG), PARAMETER :: coordinate_no_radial_interpolation_type=0
  INTEGER(INTG), PARAMETER :: coordinate_radial_interpolation_type=1
  INTEGER(INTG), PARAMETER :: coordinate_radial_squared_interpolation_type=2
  INTEGER(INTG), PARAMETER :: coordinate_radial_cubed_interpolation_type=3
  
  INTEGER(INTG), PARAMETER :: coordinate_jacobian_no_type=0
  INTEGER(INTG), PARAMETER :: coordinate_jacobian_line_type=1
  INTEGER(INTG), PARAMETER :: coordinate_jacobian_area_type=2
  INTEGER(INTG), PARAMETER :: coordinate_jacobian_volume_type=3
  
  !Module types

  TYPE coordinate_systems_type
    INTEGER(INTG) :: number_of_coordinate_systems
    TYPE(coordinate_system_ptr_type), POINTER :: coordinate_systems(:)
  END TYPE coordinate_systems_type
  
  !Module variables

  CHARACTER(LEN=21) :: coordinate_system_type_string(5) = &
    & (/ "Rectangular Cartesian",&
    &    "Cylindrical Polar    ", &
    &    "Spherical Polar      ", &
    &    "Prolate Spheroidal   ", &
    &    "Oblate Spheroidal    " /)

  TYPE(coordinate_systems_type) :: coordinate_systems
  
  !Interfaces

  INTERFACE coordinate_convert_from_rc
    MODULE PROCEDURE coordinate_convert_from_rc_dp
    MODULE PROCEDURE coordinate_convert_from_rc_sp
  END INTERFACE !COORDINATE_CONVERT_FROM_RC

  INTERFACE coordinate_convert_to_rc
    MODULE PROCEDURE coordinate_convert_to_rc_dp
    MODULE PROCEDURE coordinate_convert_to_rc_sp
  END INTERFACE !COORDINATE_CONVERT_TO_RC

  INTERFACE coordinate_delta_calculate
    MODULE PROCEDURE coordinate_delta_calculate_dp
    !MODULE PROCEDURE COORDINATE_DELTA_CALCULATE_SP
  END INTERFACE !COORDINATE_DELTA_CALCULATE

  INTERFACE dxz
    MODULE PROCEDURE dxz_dp
    !MODULE PROCEDURE DXZ_SP
  END INTERFACE !Dxz

  !!TODO:: CHANGE NAME TO SOMETHING MORE MEANINGFULL?
  INTERFACE d2zx
    MODULE PROCEDURE d2zx_dp
    !MODULE PROCEDURE D2ZX_SP
  END INTERFACE !D2ZX

  !!TODO:: CHANGE NAME TO SOMETHING MORE MEANINGFULL?
  INTERFACE dzx
    MODULE PROCEDURE dzx_dp
    !MODULE PROCEDURE DZX_SP
  END INTERFACE !DZX

  INTERFACE coordinate_derivative_convert_to_rc
    MODULE PROCEDURE coordinate_derivative_convert_to_rc_dp
    MODULE PROCEDURE coordinate_derivative_convert_to_rc_sp
  END INTERFACE !COORDINATE_DERIVATIVE_CONVERT_TO_RC

  PUBLIC coordinate_rectangular_cartesian_type,coordinate_cylindrical_polar_type,coordinate_spherical_polar_type, &
    & coordinate_prolate_spheroidal_type,coordinate_oblate_spheroidal_type

  PUBLIC coordinate_no_radial_interpolation_type,coordinate_radial_interpolation_type, &
    & coordinate_radial_squared_interpolation_type,coordinate_radial_cubed_interpolation_type
  
  PUBLIC coordinate_jacobian_no_type,coordinate_jacobian_line_type,coordinate_jacobian_area_type,coordinate_jacobian_volume_type
  
  PUBLIC coordinate_system_type_string

  PUBLIC coordinate_convert_from_rc,coordinate_convert_to_rc,coordinate_delta_calculate,coordinate_derivative_norm, &
    & coordinate_interpolation_adjust,coordinate_interpolation_parameters_adjust,coordinate_metrics_calculate
  
  PUBLIC coordinate_system_dimension_get,coordinate_system_dimension_set

  PUBLIC coordinate_system_focus_get,coordinate_system_focus_set

  PUBLIC coordinates_radialinterpolationtypeget,coordinates_radialinterpolationtypeset

  PUBLIC coordinate_system_type_get,coordinate_system_type_set

  PUBLIC coordinate_system_origin_get,coordinate_system_origin_set
  
  PUBLIC coordinate_system_orientation_get,coordinate_system_orientation_set

  PUBLIC coordinate_system_create_start,coordinate_system_create_finish

  PUBLIC coordinate_system_destroy

  PUBLIC coordinate_derivative_convert_to_rc

  PUBLIC coordinate_system_user_number_find
  
  PUBLIC coordinate_systems_initialise,coordinate_systems_finalise

  PUBLIC coordinates_materialsystemcalculate
  
CONTAINS

  !
  !================================================================================================================================
  !

  FUNCTION coordinate_convert_from_rc_dp(COORDINATE_SYSTEM,Z,ERR,ERROR)
  
    !Argument variables
    TYPE(coordinate_system_type), INTENT(IN) :: COORDINATE_SYSTEM
    REAL(DP), INTENT(IN) :: Z(:)
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Function variable
    REAL(DP) :: COORDINATE_CONVERT_FROM_RC_DP(size(z,1))
    !Local variables
    REAL(DP) :: A1,A2,A3,A4,A5,A6,A7,A8,A9,FOCUS
    
    enters("COORDINATE_CONVERT_FROM_RC_DP",err,error,*999)

    coordinate_convert_from_rc_dp=0.0_dp

    IF(SIZE(z,1)<coordinate_system%NUMBER_OF_DIMENSIONS) &
      & CALL flagerror("Size of Z is less than the number of dimensions.",err,error,*999)
    
    SELECT CASE(coordinate_system%TYPE)
    CASE(coordinate_rectangular_cartesian_type)
      coordinate_convert_from_rc_dp(1:coordinate_system%NUMBER_OF_DIMENSIONS)=z(1:coordinate_system%NUMBER_OF_DIMENSIONS)
    CASE(coordinate_cylindrical_polar_type)
      SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
      CASE(2)
        coordinate_convert_from_rc_dp(1)=sqrt(z(1)**2+z(2)**2)
        coordinate_convert_from_rc_dp(2)=atan2(z(1),z(2))
      CASE(3)
        coordinate_convert_from_rc_dp(1)=sqrt(z(1)**2+z(2)**2)
        coordinate_convert_from_rc_dp(2)=atan2(z(1),z(2))
        coordinate_convert_from_rc_dp(3)=z(3)
      CASE DEFAULT
        CALL flagerror("Invalid number of coordinates.",err,error,*999)
      END SELECT
      IF(coordinate_convert_from_rc_dp(2)<0.0_dp) &
        & coordinate_convert_from_rc_dp(2)=coordinate_convert_from_rc_dp(2)+2.0_dp*pi !reference coordinate 0->2*pi
    CASE(coordinate_spherical_polar_type)
      IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
        coordinate_convert_from_rc_dp(1)=sqrt(z(1)**2+z(2)**2+z(3)**2)
        IF(abs(z(1))>=zero_tolerance.OR.abs(z(2))>=zero_tolerance) THEN
          coordinate_convert_from_rc_dp(2)=atan2(z(2),z(1))
        ELSE
          coordinate_convert_from_rc_dp(2)=0.0_dp
        ENDIF
        a1=sqrt(z(1)**2+z(2)**2)
        IF(abs(z(3))>=zero_tolerance.OR.abs(a1)>=zero_tolerance) THEN
          coordinate_convert_from_rc_dp(3)=atan2(z(3),a1)
        ELSE
          coordinate_convert_from_rc_dp(3)=0.0_dp
        ENDIF
      ELSE
        CALL flagerror("Invalid number of coordinates.",err,error,*999)
      ENDIF
    CASE(coordinate_prolate_spheroidal_type)
      focus=coordinate_system%FOCUS
      IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
        a1=z(1)**2+z(2)**2+z(3)**2-focus**2
        a2=sqrt(a1**2+4.0_dp*(focus**2)*(z(2)**2+z(3)**2))
        a3=2.0_dp*focus**2
        a4=max((a2+a1)/a3,0.0_dp)
        a5=max((a2-a1)/a3,0.0_dp)
        a6=sqrt(a4)
        a7=min(sqrt(a5),1.0_dp)
        IF(abs(a7)<=1.0_dp) THEN
          a8=asin(a7)
        ELSE
          a8=0.0_dp
          CALL flag_warning("Put A8=0 since ABS(A8)>1.",err,error,*999)
        ENDIF
        IF((abs(z(3))<zero_tolerance).OR.(abs(a6)<zero_tolerance).OR.(abs(a7)<zero_tolerance)) THEN
          a9=0.0_dp
        ELSE
          IF(abs(a6*a7)>0.0_dp) THEN
            a9=z(3)/(focus*a6*a7)
          ELSE
            a9=0.0_dp
            CALL flag_warning("Put A9=0 since A6*A7=0.",err,error,*999)
          ENDIF
          IF(a9>=1.0_dp) THEN
            a9=pi/2.0_dp
          ELSE IF(a9<=-1.0_dp) THEN
            a9=-pi/2.0_dp
          ELSE
            a9=asin(a9)
          ENDIF
        ENDIF
        coordinate_convert_from_rc_dp(1)=log(a6+sqrt(a4+1.0_dp))
        IF(abs(z(1))>=zero_tolerance) THEN
          coordinate_convert_from_rc_dp(2)=a8
        ELSE
          coordinate_convert_from_rc_dp(2)=pi-a8
        ENDIF
        IF(abs(z(2))>zero_tolerance) THEN
          coordinate_convert_from_rc_dp(3)=mod(a9+2.0_dp*pi,2.0_dp*pi)
        ELSE
          coordinate_convert_from_rc_dp(3)=pi-a9
        ENDIF
      ELSE
        CALL flagerror("Invalid number of coordinates.",err,error,*999)
      ENDIF
    CASE(coordinate_oblate_spheroidal_type)
      CALL flagerror("Not implemented.",err,error,*999)
    CASE DEFAULT
      CALL flagerror("Invalid coordinate type.",err,error,*999)
    END SELECT

    exits("COORDINATE_CONVERT_FROM_RC_DP")
    RETURN
999 errorsexits("COORDINATE_CONVERT_FROM_RC_DP",err,error)
    RETURN 
  END FUNCTION coordinate_convert_from_rc_dp
  
  !
  !================================================================================================================================
  !

  FUNCTION coordinate_convert_from_rc_sp(COORDINATE_SYSTEM,Z,ERR,ERROR)
  
    !Argument variables
    TYPE(coordinate_system_type), INTENT(IN) :: COORDINATE_SYSTEM
    REAL(SP), INTENT(IN) :: Z(:)
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Function variable
    REAL(SP) :: COORDINATE_CONVERT_FROM_RC_SP(size(z,1))
    !Local variables
    REAL(SP) :: A1,A2,A3,A4,A5,A6,A7,A8,A9,FOCUS
    
    enters("COORDINATE_CONVERT_FROM_RC_SP",err,error,*999)

    coordinate_convert_from_rc_sp=0.0_sp
    
    IF(SIZE(z,1)<coordinate_system%NUMBER_OF_DIMENSIONS) &
      & CALL flagerror("Size of Z is less than the number of dimensions.",err,error,*999)
    
    SELECT CASE(coordinate_system%TYPE)
    CASE(coordinate_rectangular_cartesian_type)
      coordinate_convert_from_rc_sp(1:coordinate_system%NUMBER_OF_DIMENSIONS)=z(1:coordinate_system%NUMBER_OF_DIMENSIONS)
    CASE(coordinate_cylindrical_polar_type)
      SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
      CASE(2)
        coordinate_convert_from_rc_sp(1)=sqrt(z(1)**2+z(2)**2)
        coordinate_convert_from_rc_sp(2)=atan2(z(1),z(2))
      CASE(3)
        coordinate_convert_from_rc_sp(1)=sqrt(z(1)**2+z(2)**2)
        coordinate_convert_from_rc_sp(2)=atan2(z(1),z(2))
        coordinate_convert_from_rc_sp(3)=z(3)
      CASE DEFAULT
        CALL flagerror("Invalid number of coordinates.",err,error,*999)
      END SELECT
      IF(coordinate_convert_from_rc_sp(2)<0.0_sp)  &
        & coordinate_convert_from_rc_sp(2)=coordinate_convert_from_rc_sp(2)+2.0_sp*REAL(PI,SP) !reference coordinate 0->2*pi
    CASE(coordinate_spherical_polar_type)
      IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
        coordinate_convert_from_rc_sp(1)=sqrt(z(1)**2+z(2)**2+z(3)**2)
        IF(abs(z(1))>=zero_tolerance_sp.OR.abs(z(2))>zero_tolerance_sp) THEN
          coordinate_convert_from_rc_sp(2)=atan2(z(2),z(1))
        ELSE
          coordinate_convert_from_rc_sp(2)=0.0_sp
        ENDIF
        a1=sqrt(z(1)**2+z(2)**2)
        IF(abs(z(3))>=zero_tolerance_sp.OR.abs(a1)>zero_tolerance_sp) THEN
          coordinate_convert_from_rc_sp(3)=atan2(z(3),a1)
        ELSE
          coordinate_convert_from_rc_sp(3)=0.0_sp
        ENDIF
      ELSE
        CALL flagerror("Invalid number of coordinates.",err,error,*999)
      ENDIF
    CASE(coordinate_prolate_spheroidal_type)
      focus=REAL(coordinate_system%focus,sp)
      IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
        a1=z(1)**2+z(2)**2+z(3)**2-focus**2
        a2=sqrt(a1**2+4.0_sp*(focus**2)*(z(2)**2+z(3)**2))
        a3=2.0_sp*focus**2
        a4=max((a2+a1)/a3,0.0_sp)
        a5=max((a2-a1)/a3,0.0_sp)
        a6=sqrt(a4)
        a7=min(sqrt(a5),1.0_sp)
        IF(abs(a7)<=1.0_sp) THEN
          a8=asin(a7)
        ELSE
          a8=0.0_sp
          CALL flag_warning("Put A8=0 since ABS(A8)>1.",err,error,*999)
        ENDIF
        IF((abs(z(3))<zero_tolerance_sp).OR.(abs(a6)<zero_tolerance_sp).OR.(abs(a7)<zero_tolerance_sp)) THEN
          a9=0.0_sp
        ELSE
          IF(abs(a6*a7)>zero_tolerance_sp) THEN
            a9=z(3)/(focus*a6*a7)
          ELSE
            a9=0.0_sp
            CALL flag_warning("Put A9=0 since A6*A7=0.",err,error,*999)
          ENDIF
          IF(a9>=1.0_sp) THEN
            a9=REAL(pi,sp)/2.0_SP
          ELSE IF(a9<=-1.0_sp) THEN
            a9=-REAL(pi,sp)/2.0_SP
          ELSE
            a9=asin(a9)
          ENDIF
        ENDIF
        coordinate_convert_from_rc_sp(1)=log(a6+sqrt(a4+1.0_sp))
        IF(abs(z(1))>=zero_tolerance_sp) THEN
          coordinate_convert_from_rc_sp(2)=a8
        ELSE
          coordinate_convert_from_rc_sp(2)=REAL(pi,sp)-A8
        ENDIF
        IF(abs(z(2))>=zero_tolerance_sp) THEN
          coordinate_convert_from_rc_sp(3)=mod(a9+2.0_sp*REAL(PI,SP),2.0_SP*&
            & REAL(PI,SP))
        ELSE
          coordinate_convert_from_rc_sp(3)=REAL(pi,sp)-A9
        ENDIF
      ELSE
        CALL flagerror("Invalid number of coordinates.",err,error,*999)
      ENDIF
    CASE(coordinate_oblate_spheroidal_type)
      CALL flagerror("Not implemented.",err,error,*999)
    CASE DEFAULT
      CALL flagerror("Invalid coordinate type.",err,error,*999)
    END SELECT

    exits("COORDINATE_CONVERT_FROM_RC_SP")
    RETURN
999 errorsexits("COORDINATE_CONVERT_FROM_RC_SP",err,error)
    RETURN 
  END FUNCTION coordinate_convert_from_rc_sp

  !
  !================================================================================================================================
  !

  FUNCTION coordinate_convert_to_rc_dp(COORDINATE_SYSTEM,X,ERR,ERROR)
  
    !Argument variables
    TYPE(coordinate_system_type), INTENT(IN) :: COORDINATE_SYSTEM
    REAL(DP), INTENT(IN) :: X(:)
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Function variable
    REAL(DP) :: COORDINATE_CONVERT_TO_RC_DP(size(x,1))
    !Local variables
    REAL(DP) :: FOCUS
    
    enters("COORDINATE_CONVERT_TO_RC_DP",err,error,*999)
    
    coordinate_convert_to_rc_dp=0.0_dp

    IF(SIZE(x,1)<coordinate_system%NUMBER_OF_DIMENSIONS) &
      & CALL flagerror("Size of X is less than the number of dimensions.",err,error,*999)

    SELECT CASE(coordinate_system%TYPE)
    CASE(coordinate_rectangular_cartesian_type)
      coordinate_convert_to_rc_dp(1:coordinate_system%NUMBER_OF_DIMENSIONS)=x(1:coordinate_system%NUMBER_OF_DIMENSIONS)
    CASE(coordinate_cylindrical_polar_type)
      SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
      CASE(2)
        coordinate_convert_to_rc_dp(1)=x(1)*cos(x(2))
        coordinate_convert_to_rc_dp(2)=x(1)*sin(x(2))
      CASE(3)
        coordinate_convert_to_rc_dp(1)=x(1)*cos(x(2))
        coordinate_convert_to_rc_dp(2)=x(1)*sin(x(2))
        coordinate_convert_to_rc_dp(3)=x(3)
      CASE DEFAULT
        CALL flagerror("Invalid number of coordinates.",err,error,*999)
      END SELECT
    CASE(coordinate_spherical_polar_type)
      IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN  
        coordinate_convert_to_rc_dp(1)=x(1)*cos(x(2))*cos(x(3))
        coordinate_convert_to_rc_dp(2)=x(1)*sin(x(2))*cos(x(3))
        coordinate_convert_to_rc_dp(3)=x(1)*sin(x(3))
      ELSE
        CALL flagerror("Invalid number of coordinates.",err,error,*999)
      ENDIF
    CASE(coordinate_prolate_spheroidal_type)
      IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
        focus=coordinate_system%FOCUS
        coordinate_convert_to_rc_dp(1)=focus*cosh(x(1))*cos(x(2))
        coordinate_convert_to_rc_dp(2)=focus*sinh(x(1))*sin(x(2))*cos(x(3))
        coordinate_convert_to_rc_dp(3)=focus*sinh(x(1))*sin(x(2))*sin(x(3))
      ELSE
        CALL flagerror("Invalid number of coordinates.",err,error,*999)
      ENDIF
    CASE(coordinate_oblate_spheroidal_type)
      IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
        focus=coordinate_system%FOCUS
        coordinate_convert_to_rc_dp(1)=focus*cosh(x(1))*cos(x(2))*cos(x(3))
        coordinate_convert_to_rc_dp(2)=focus*sinh(x(1))*sin(x(2))
        coordinate_convert_to_rc_dp(3)=focus*cosh(x(1))*cos(x(2))*sin(x(3))
      ELSE
        CALL flagerror("Invalid number of coordinates.",err,error,*999)
      ENDIF
    CASE DEFAULT
      CALL flagerror("Invalid coordinate type.",err,error,*999)
    END SELECT

    exits("COORDINATE_CONVERT_TO_RC_DP")
    RETURN
999 errorsexits("COORDINATE_CONVERT_TO_RC_DP",err,error)
    RETURN 
  END FUNCTION coordinate_convert_to_rc_dp

  !
  !================================================================================================================================
  !

  FUNCTION coordinate_convert_to_rc_sp(COORDINATE_SYSTEM,X,ERR,ERROR)
  
    !Argument variables
    TYPE(coordinate_system_type), INTENT(IN) :: COORDINATE_SYSTEM
    REAL(SP), INTENT(IN) :: X(:)
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Function variable
    REAL(SP) :: COORDINATE_CONVERT_TO_RC_SP(size(x,1))
    !Local variables
    REAL(SP) :: FOCUS
    
    enters("COORDINATE_CONVERT_TO_RC_SP",err,error,*999)
    
    coordinate_convert_to_rc_sp=0.0_sp

    IF(SIZE(x,1)<coordinate_system%NUMBER_OF_DIMENSIONS) &
      & CALL flagerror("Size of X is less than the number of dimensions.",err,error,*999)

    SELECT CASE(coordinate_system%TYPE)
    CASE(coordinate_rectangular_cartesian_type)
      coordinate_convert_to_rc_sp(1:coordinate_system%NUMBER_OF_DIMENSIONS)=x(1:coordinate_system%NUMBER_OF_DIMENSIONS)
    CASE(coordinate_cylindrical_polar_type)
      SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
      CASE(2)
        coordinate_convert_to_rc_sp(1)=x(1)*cos(x(2))
        coordinate_convert_to_rc_sp(2)=x(1)*sin(x(2))
      CASE(3)
        coordinate_convert_to_rc_sp(1)=x(1)*cos(x(2))
        coordinate_convert_to_rc_sp(2)=x(1)*sin(x(2))
        coordinate_convert_to_rc_sp(3)=x(3)
      CASE DEFAULT
        CALL flagerror("Invalid number of coordinates.",err,error,*999)
      END SELECT
    CASE(coordinate_spherical_polar_type)
      IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN  
        coordinate_convert_to_rc_sp(1)=x(1)*cos(x(2))*cos(x(3))
        coordinate_convert_to_rc_sp(2)=x(1)*sin(x(2))*cos(x(3))
        coordinate_convert_to_rc_sp(3)=x(1)*sin(x(3))
      ELSE
        CALL flagerror("Invalid number of coordinates.",err,error,*999)
      ENDIF
    CASE(coordinate_prolate_spheroidal_type)
      IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
        focus=REAL(coordinate_system%focus,sp)
        coordinate_convert_to_rc_sp(1)=focus*cosh(x(1))*cos(x(2))
        coordinate_convert_to_rc_sp(2)=focus*sinh(x(1))*sin(x(2))*cos(x(3))
        coordinate_convert_to_rc_sp(3)=focus*sinh(x(1))*sin(x(2))*sin(x(3))
      ELSE
        CALL flagerror("Invalid number of coordinates.",err,error,*999)
      ENDIF
    CASE(coordinate_oblate_spheroidal_type)
      IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
        focus=REAL(coordinate_system%focus,sp)
        coordinate_convert_to_rc_sp(1)=focus*cosh(x(1))*cos(x(2))*cos(x(3))
        coordinate_convert_to_rc_sp(2)=focus*sinh(x(1))*sin(x(2))
        coordinate_convert_to_rc_sp(3)=focus*cosh(x(1))*cos(x(2))*sin(x(3))
      ELSE
        CALL flagerror("Invalid number of coordinates.",err,error,*999)
      ENDIF
    CASE DEFAULT
      CALL flagerror("Invalid coordinate type.",err,error,*999)
    END SELECT

    exits("COORDINATE_CONVERT_TO_RC_SP")
    RETURN
999 errorsexits("COORDINATE_CONVERT_TO_RC_SP",err,error)
    RETURN 
  END FUNCTION coordinate_convert_to_rc_sp

  !
  !================================================================================================================================
  !

  FUNCTION coordinate_delta_calculate_dp(COORDINATE_SYSTEM,X,Y,ERR,ERROR)
  
    !Argument variables
    TYPE(coordinate_system_type), INTENT(IN) :: COORDINATE_SYSTEM
    REAL(DP), INTENT(IN) :: X(:)
    REAL(DP), INTENT(IN) :: Y(:)
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Function variable
    REAL(DP) :: COORDINATE_DELTA_CALCULATE_DP(size(x,1))
    !Local variables

    enters("COORDINATE_DELTA_CALCULATE_DP",err,error,*999)

    coordinate_delta_calculate_dp=0.0_dp

    IF(SIZE(x,1)<coordinate_system%NUMBER_OF_DIMENSIONS) &
      & CALL flagerror("Size of X is less than the number of dimensions.",err,error,*999)

    IF(SIZE(x,1)/=SIZE(y,1)) &
      & CALL flagerror("Size of X is different to the size of Y.",err,error,*999)
   
    coordinate_delta_calculate_dp(1:coordinate_system%NUMBER_OF_DIMENSIONS)=y(1:coordinate_system%NUMBER_OF_DIMENSIONS)- &
      & x(1:coordinate_system%NUMBER_OF_DIMENSIONS)
    SELECT CASE(coordinate_system%TYPE)
    CASE(coordinate_rectangular_cartesian_type)
      !Do nothing
    CASE(coordinate_cylindrical_polar_type)
      CALL flagerror("Not implemented.",err,error,*999)
    CASE(coordinate_spherical_polar_type)
      CALL flagerror("Not implemented.",err,error,*999)
    CASE(coordinate_prolate_spheroidal_type)
      CALL flagerror("Not implemented.",err,error,*999)
    CASE(coordinate_oblate_spheroidal_type)
      CALL flagerror("Not implemented.",err,error,*999)
    CASE DEFAULT
      CALL flagerror("Invalid coordinate type.",err,error,*999)
    END SELECT

    exits("COORDINATE_DELTA_CALCULATE_DP")
    RETURN
999 errorsexits("COORDINATE_DELTA_CALCULATE_DP",err,error)
    RETURN 
  END FUNCTION coordinate_delta_calculate_dp

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_metrics_calculate(COORDINATE_SYSTEM,JACOBIAN_TYPE,METRICS,ERR,ERROR,*)

    !Argument variables
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    INTEGER(INTG), INTENT(IN) :: JACOBIAN_TYPE
    TYPE(field_interpolated_point_metrics_type), POINTER :: METRICS
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables
    INTEGER(INTG) :: mi,ni,nu
    REAL(DP) :: DET_GL,DET_DX_DXI,DX_DXI2(3),DX_DXI3(3),FF,G1,G3,LENGTH,MU,R,RC,RCRC,RR,SCALE
    TYPE(field_interpolated_point_type), POINTER :: INTERPOLATED_POINT
    TYPE(varying_string) :: LOCAL_ERROR

    NULLIFY(interpolated_point)

    enters("COORDINATE_METRICS_CALCULATE",err,error,*999)

    IF(ASSOCIATED(coordinate_system)) THEN
      IF(ASSOCIATED(metrics)) THEN
        interpolated_point=>metrics%INTERPOLATED_POINT
        IF(ASSOCIATED(interpolated_point)) THEN
          IF(interpolated_point%PARTIAL_DERIVATIVE_TYPE>=first_part_deriv) THEN

            SELECT CASE(metrics%NUMBER_OF_XI_DIMENSIONS)
            CASE(1)
              !Calculate the derivatives of X with respect to XI
              nu=partial_derivative_first_derivative_map(1)
              metrics%DX_DXI(1:metrics%NUMBER_OF_X_DIMENSIONS,1)=interpolated_point%VALUES(1:metrics%NUMBER_OF_X_DIMENSIONS,nu)
              !Initialise the covariant metric tensor to the identity matrix
              metrics%GL(1,1)=1.0_dp
            CASE(2)
              !Calculate the derivatives of X with respect to XI
              nu=partial_derivative_first_derivative_map(1)
              metrics%DX_DXI(1:metrics%NUMBER_OF_X_DIMENSIONS,1)=interpolated_point%VALUES(1:metrics%NUMBER_OF_X_DIMENSIONS,nu)
              nu=partial_derivative_first_derivative_map(2)
              metrics%DX_DXI(1:metrics%NUMBER_OF_X_DIMENSIONS,2)=interpolated_point%VALUES(1:metrics%NUMBER_OF_X_DIMENSIONS,nu)
              !Initialise the covariant metric tensor to the identity matrix
              metrics%GL(1,1)=1.0_dp
              metrics%GL(1,2)=0.0_dp
              metrics%GL(2,1)=0.0_dp
              metrics%GL(2,2)=1.0_dp
            CASE(3)
              !Calculate the derivatives of X with respect to XI
              nu=partial_derivative_first_derivative_map(1)
              metrics%DX_DXI(1:metrics%NUMBER_OF_X_DIMENSIONS,1)=interpolated_point%VALUES(1:metrics%NUMBER_OF_X_DIMENSIONS,nu)
              nu=partial_derivative_first_derivative_map(2)
              metrics%DX_DXI(1:metrics%NUMBER_OF_X_DIMENSIONS,2)=interpolated_point%VALUES(1:metrics%NUMBER_OF_X_DIMENSIONS,nu)
              nu=partial_derivative_first_derivative_map(3)
              metrics%DX_DXI(1:metrics%NUMBER_OF_X_DIMENSIONS,3)=interpolated_point%VALUES(1:metrics%NUMBER_OF_X_DIMENSIONS,nu)
              !Initialise the covariant metric tensor to the identity matrix
              metrics%GL(1,1)=1.0_dp
              metrics%GL(1,2)=0.0_dp
              metrics%GL(1,3)=0.0_dp
              metrics%GL(2,1)=0.0_dp
              metrics%GL(2,2)=1.0_dp
              metrics%GL(2,3)=0.0_dp
              metrics%GL(3,1)=0.0_dp
              metrics%GL(3,2)=0.0_dp
              metrics%GL(3,3)=1.0_dp
            CASE DEFAULT
              CALL flagerror("Not implemented.",err,error,*999)
            END SELECT
                        
            !Calculate the covariant metric tensor GL(i,j)
            SELECT CASE(coordinate_system%TYPE)
            CASE(coordinate_rectangular_cartesian_type)
              SELECT CASE(metrics%NUMBER_OF_X_DIMENSIONS)
              CASE(1)
                DO mi=1,metrics%NUMBER_OF_XI_DIMENSIONS
                  DO ni=1,metrics%NUMBER_OF_XI_DIMENSIONS
                    metrics%GL(mi,ni)=metrics%DX_DXI(1,mi)*metrics%DX_DXI(1,ni)                    
                  ENDDO !ni
                ENDDO !mi
              CASE(2)
                DO mi=1,metrics%NUMBER_OF_XI_DIMENSIONS
                  DO ni=1,metrics%NUMBER_OF_XI_DIMENSIONS
                    metrics%GL(mi,ni)=metrics%DX_DXI(1,mi)*metrics%DX_DXI(1,ni)+ &
                      & metrics%DX_DXI(2,mi)*metrics%DX_DXI(2,ni)
                  ENDDO !ni
                ENDDO !mi
              CASE(3)
                DO mi=1,metrics%NUMBER_OF_XI_DIMENSIONS
                  DO ni=1,metrics%NUMBER_OF_XI_DIMENSIONS
                    metrics%GL(mi,ni)=metrics%DX_DXI(1,mi)*metrics%DX_DXI(1,ni)+ &
                      & metrics%DX_DXI(2,mi)*metrics%DX_DXI(2,ni)+ &
                      & metrics%DX_DXI(3,mi)*metrics%DX_DXI(3,ni)
                  ENDDO !ni
                ENDDO !mi
              CASE DEFAULT
                local_error=trim(number_to_vstring(metrics%NUMBER_OF_X_DIMENSIONS,"*",err,error))// &
                  & " is an invalid number of dimensions for a rectangular cartesian coordinate system."
                CALL flagerror(local_error,err,error,*999)
              END SELECT
            CASE(coordinate_cylindrical_polar_type)
              r=interpolated_point%VALUES(1,1)
              rr=r*r
              IF(metrics%NUMBER_OF_X_DIMENSIONS==2) THEN
                DO mi=1,metrics%NUMBER_OF_XI_DIMENSIONS
                  DO ni=1,metrics%NUMBER_OF_XI_DIMENSIONS
                    metrics%GL(mi,ni)=metrics%DX_DXI(1,mi)*metrics%DX_DXI(1,ni)+rr*metrics%DX_DXI(2,mi)*metrics%DX_DXI(2,ni)
                  ENDDO !ni
                ENDDO !mi
              ELSE IF(metrics%NUMBER_OF_X_DIMENSIONS==3) THEN
                DO mi=1,metrics%NUMBER_OF_XI_DIMENSIONS
                  DO ni=1,metrics%NUMBER_OF_XI_DIMENSIONS
                    metrics%GL(mi,ni)=metrics%DX_DXI(1,mi)*metrics%DX_DXI(1,ni)+rr*metrics%DX_DXI(2,mi)*metrics%DX_DXI(2,ni)+ &
                      & metrics%DX_DXI(3,mi)*metrics%DX_DXI(3,ni)
                  ENDDO !ni
                ENDDO !mi
              ELSE
                local_error=trim(number_to_vstring(metrics%NUMBER_OF_X_DIMENSIONS,"*",err,error))// &
                  & " is an invalid number of dimensions for a cylindrical polar coordinate system."
                CALL flagerror(local_error,err,error,*999)
              ENDIF
            CASE(coordinate_spherical_polar_type)
              r=interpolated_point%VALUES(1,1)
              rr=r*r
              rc=r*cos(interpolated_point%VALUES(3,1))
              rcrc=rc*rc          
              DO mi=1,metrics%NUMBER_OF_XI_DIMENSIONS
                DO ni=1,metrics%NUMBER_OF_XI_DIMENSIONS
                  metrics%GL(mi,ni)=metrics%DX_DXI(1,mi)*metrics%DX_DXI(1,ni)+rcrc*metrics%DX_DXI(2,mi)*metrics%DX_DXI(2,ni)+ &
                    & rr*metrics%DX_DXI(3,mi)*metrics%DX_DXI(3,ni)
                ENDDO !ni
              ENDDO !mi
            CASE(coordinate_prolate_spheroidal_type)
              IF(abs(interpolated_point%VALUES(2,1))<zero_tolerance) THEN
                CALL flag_warning("Mu is zero.",err,error,*999)
              ELSE
                ff=coordinate_system%FOCUS*coordinate_system%FOCUS
                r=interpolated_point%VALUES(1,1)
                mu=interpolated_point%VALUES(2,1)
                g1=ff*(sinh(r)*sinh(r)+sin(mu)*sin(mu))
                g3=ff*sinh(r)*sinh(r)*sin(mu)*sin(mu)
                IF(metrics%NUMBER_OF_X_DIMENSIONS==2) THEN
                  DO mi=1,metrics%NUMBER_OF_XI_DIMENSIONS
                    DO ni=1,metrics%NUMBER_OF_XI_DIMENSIONS
                      metrics%GL(mi,ni)=g1*(metrics%DX_DXI(1,mi)*metrics%DX_DXI(1,ni)+metrics%DX_DXI(2,mi)*metrics%DX_DXI(2,ni))
                    ENDDO !ni
                  ENDDO !mi
                ELSE IF(metrics%NUMBER_OF_X_DIMENSIONS==3) THEN
                  DO mi=1,metrics%NUMBER_OF_XI_DIMENSIONS
                    DO ni=1,metrics%NUMBER_OF_XI_DIMENSIONS
                      metrics%GL(mi,ni)=g1*(metrics%DX_DXI(1,mi)*metrics%DX_DXI(1,ni)+metrics%DX_DXI(2,mi)*metrics%DX_DXI(2,ni))+ &
                        & g3*metrics%DX_DXI(3,mi)*metrics%DX_DXI(3,ni)
                    ENDDO !ni
                  ENDDO !mi
                ELSE
                  local_error=trim(number_to_vstring(metrics%NUMBER_OF_X_DIMENSIONS,"*",err,error))// &
                    & " is an invalid number of dimensions for a prolate spheroidal coordinate system."
                  CALL flagerror(local_error,err,error,*999)
                ENDIF
              ENDIF
            CASE(coordinate_oblate_spheroidal_type)
              CALL flagerror("Not implemented.",err,error,*999)
            CASE DEFAULT
              local_error="The coordinate system type of "//trim(number_to_vstring(coordinate_system%TYPE,"*",err,error))// &
                & " is invalid."
              CALL flagerror(local_error,err,error,*999)
            END SELECT
            
            !Calcualte the contravariant metric tensor
            CALL invert(metrics%GL(1:metrics%NUMBER_OF_XI_DIMENSIONS,1:metrics%NUMBER_OF_XI_DIMENSIONS), &
              & metrics%GU(1:metrics%NUMBER_OF_XI_DIMENSIONS,1:metrics%NUMBER_OF_XI_DIMENSIONS),det_gl, &
              & err,error,*999)

            !Calculate the Jacobian
            SELECT CASE(jacobian_type)
            CASE(coordinate_jacobian_no_type)
              metrics%JACOBIAN=0.0
              metrics%JACOBIAN_TYPE=coordinate_jacobian_no_type
            CASE(coordinate_jacobian_line_type)
              metrics%JACOBIAN=sqrt(abs(metrics%GL(1,1)))
              metrics%JACOBIAN_TYPE=coordinate_jacobian_line_type
            CASE(coordinate_jacobian_area_type)
              IF(metrics%NUMBER_OF_XI_DIMENSIONS==3) THEN
                metrics%JACOBIAN=sqrt(abs(det_gl*metrics%GU(3,3)))
              ELSE
                metrics%JACOBIAN=sqrt(abs(det_gl))
              ENDIF
              metrics%JACOBIAN_TYPE=coordinate_jacobian_area_type
            CASE(coordinate_jacobian_volume_type)
              metrics%JACOBIAN=sqrt(abs(det_gl))
              metrics%JACOBIAN_TYPE=coordinate_jacobian_volume_type
            CASE DEFAULT
              local_error="The Jacobian type of "//trim(number_to_vstring(jacobian_type,"*",err,error))// &
                & " is invalid."
              CALL flagerror(local_error,err,error,*999)
            END SELECT
            
            !Calculate the derivatives of Xi with respect to X - DXI_DX
            IF(metrics%NUMBER_OF_XI_DIMENSIONS==metrics%NUMBER_OF_X_DIMENSIONS) THEN
              CALL invert(metrics%DX_DXI,metrics%DXI_DX,det_dx_dxi,err,error,*999)
            ELSE
              !We have a line or a surface embedded in a higher dimensional space
              SELECT CASE(metrics%NUMBER_OF_XI_DIMENSIONS)
              CASE(1)
                !Line in space
                SELECT CASE(metrics%NUMBER_OF_X_DIMENSIONS)
                CASE(2)
                  IF(interpolated_point%PARTIAL_DERIVATIVE_TYPE>first_part_deriv) THEN
                    !We have curvature information. Form the frenet vector frame.
                    !Calculate the normal vector from the normalised second derivative of the position vector.
                    nu=partial_derivative_second_derivative_map(1)
                    dx_dxi2=normalise(interpolated_point%VALUES(1:2,nu),err,error)
                    IF(err/=0) GOTO 999
                  ELSE
                    !No curvature information but obtain other normal frenet vector by rotating tangent vector 90 deg.
                    dx_dxi2(1)=-1.0_dp*metrics%DX_DXI(2,1)
                    dx_dxi2(2)=metrics%DX_DXI(1,1)                    
                  ENDIF
                  det_dx_dxi=metrics%DX_DXI(1,1)*dx_dxi2(2)-metrics%DX_DXI(2,1)*dx_dxi2(1)
                  IF(abs(det_dx_dxi)>zero_tolerance) THEN
                    metrics%DXI_DX(1,1)=dx_dxi2(2)/det_dx_dxi
                    metrics%DXI_DX(1,2)=-1.0_dp*dx_dxi2(1)/det_dx_dxi
                    !Normalise to ensure that g^11=g^1.g^1
                    length=l2norm(metrics%DXI_DX(1,1:2))
                    scale=sqrt(abs(metrics%GU(1,1)))/length
                    metrics%DXI_DX(1,1:2)=scale*metrics%DXI_DX(1,1:2)
                  ELSE
                    CALL flag_warning("Zero determinant. Unable to obtain dxi/dx.",err,error,*999)
                    metrics%DXI_DX=0.0_dp                    
                  ENDIF
                CASE(3)
                  IF(interpolated_point%PARTIAL_DERIVATIVE_TYPE>first_part_deriv) THEN
                    !We have curvature information. Form the frenet vector frame.
                    !Calculate the normal vector from the normalised second derivative of the position vector.
                    nu=partial_derivative_second_derivative_map(1)
                    dx_dxi2=normalise(interpolated_point%VALUES(1:3,nu),err,error)
                    IF(err/=0) GOTO 999
                    !Calculate the bi-normal vector from the normalised cross product of the tangent and normal vectors
                    CALL norm_cross_product(metrics%DX_DXI(1:3,1),dx_dxi2,dx_dxi3,err,error,*999)
                    det_dx_dxi=metrics%DX_DXI(1,1)*(dx_dxi2(2)*dx_dxi3(3)-dx_dxi2(3)*dx_dxi3(2))+ &
                      & dx_dxi2(1)*(metrics%DX_DXI(3,1)*dx_dxi3(2)-dx_dxi3(3)*metrics%DX_DXI(2,1))+ &
                      & dx_dxi3(1)*(metrics%DX_DXI(2,1)*dx_dxi2(3)-metrics%DX_DXI(3,1)*dx_dxi2(2))
                    IF(abs(det_dx_dxi)>zero_tolerance) THEN
                      metrics%DXI_DX(1,1)=(dx_dxi3(3)*dx_dxi2(2)-dx_dxi2(3)*dx_dxi3(2))/det_dx_dxi
                      metrics%DXI_DX(1,2)=-1.0_dp*(dx_dxi3(3)*dx_dxi2(1)-dx_dxi2(3)*dx_dxi3(1))/det_dx_dxi
                      metrics%DXI_DX(1,3)=(dx_dxi3(2)*dx_dxi2(1)-dx_dxi2(2)*dx_dxi3(1))/det_dx_dxi
                      !Normalise to ensure that g^11=g^1.g^1
                      length=l2norm(metrics%DXI_DX(1,1:3))
                      scale=sqrt(abs(metrics%GU(1,1)))/length
                      metrics%DXI_DX(1,1:3)=scale*metrics%DX_DXI(1,1:3)
                    ELSE
                      CALL flag_warning("Zero determinant. Unable to obtain dxi/dx.",err,error,*999)
                      metrics%DXI_DX=0.0_dp                    
                    ENDIF
                  ELSE
                    metrics%DXI_DX(1,1)=metrics%DX_DXI(1,1)
                    metrics%DXI_DX(1,2)=metrics%DX_DXI(2,1)
                    metrics%DXI_DX(1,3)=metrics%DX_DXI(3,1)
                    !Normalise to ensure that g^11=g^1.g^1
                    length=l2norm(metrics%DXI_DX(1,1:3))
                    scale=sqrt(abs(metrics%GU(1,1)))/length
                    metrics%DXI_DX(1,1:3)=scale*metrics%DXI_DX(1,1:3)
                  ENDIF
                CASE DEFAULT
                  CALL flagerror("Invalid embedding of a line in space.",err,error,*999)
                END SELECT
              CASE(2)
                !Surface in space
                IF(metrics%NUMBER_OF_X_DIMENSIONS==3) THEN
                  !Surface in 3D space.
                  !Calculate the covariant vectors g^1 and g^2. These are calculated as follows:
                  !First define g_3=g_1 x g_2, and then define g^1=((g_2 x g_3)_b)/DET_GL and g^2=((g_3 x g_1)_b)/DET_GL. 
                  !The _b means lowering the index with the metric tensor of the curvilinear coordinate system.
                  !This way we have a consistent set of covariant and covariant vectors, i.e.  <g_M,g^N>=delta_M^N.
                  metrics%DXI_DX(1,1:3)=(metrics%GL(2,2)*metrics%DX_DXI(1:3,1)-metrics%GL(1,2)*metrics%DX_DXI(1:3,2))/det_gl
                  metrics%DXI_DX(2,1:3)=(metrics%GL(1,1)*metrics%DX_DXI(1:3,2)-metrics%GL(2,1)*metrics%DX_DXI(1:3,1))/det_gl
                  SELECT CASE(coordinate_system%TYPE)
                  CASE(coordinate_rectangular_cartesian_type)
                    !Do nothing
                  CASE(coordinate_cylindrical_polar_type)
                    r=interpolated_point%VALUES(1,1)
                    rr=r*r
                    metrics%DXI_DX(1:2,2)=metrics%DXI_DX(1:2,2)*rr
                  CASE(coordinate_spherical_polar_type)
                    r=interpolated_point%VALUES(1,1)
                    rr=r*r
                    rc=r*cos(interpolated_point%VALUES(3,1))
                    rcrc=rc*rc          
                    metrics%DXI_DX(1:2,2)=metrics%DXI_DX(1:2,2)*rcrc
                    metrics%DXI_DX(1:2,3)=metrics%DXI_DX(1:2,3)*rr
                  CASE(coordinate_prolate_spheroidal_type)
                    IF(abs(interpolated_point%VALUES(2,1))<zero_tolerance) THEN
                      CALL flag_warning("Mu is zero.",err,error,*999)
                    ELSE
                      ff=coordinate_system%FOCUS*coordinate_system%FOCUS
                      r=interpolated_point%VALUES(1,1)
                      mu=interpolated_point%VALUES(2,1)
                      g1=ff*(sinh(r)*sinh(r)+sin(mu)*sin(mu))
                      g3=ff*sinh(r)*sinh(r)*sin(mu)*sin(mu)
                      metrics%DXI_DX(1:2,1)=metrics%DXI_DX(1:2,1)*g1
                      metrics%DXI_DX(1:2,2)=metrics%DXI_DX(1:2,2)*g1
                      metrics%DXI_DX(1:2,3)=metrics%DXI_DX(1:2,3)*g3
                    ENDIF
                  CASE(coordinate_oblate_spheroidal_type)
                    CALL flagerror("Not implemented.",err,error,*999)
                  CASE DEFAULT
                    local_error="The coordinate system type of "//trim(number_to_vstring(coordinate_system%TYPE,"*",err,error))// &
                      & " is invalid."
                    CALL flagerror(local_error,err,error,*999)
                  END SELECT
                ELSE
                  CALL flagerror("Invalid embedding of a surface in space.",err,error,*999)
                ENDIF
              CASE DEFAULT
                CALL flagerror("Invalid embedding in space.",err,error,*999)
              END SELECT
            ENDIF
          ELSE
            CALL flagerror("Metrics interpolated point has not been interpolated to include first derivatives.",err,error,*999)
          ENDIF
        ELSE
          CALL flagerror("Metrics interpolated point is not associated.",err,error,*999)
        ENDIF
      ELSE
        CALL flagerror("Metrics is not associated.",err,error,*999)
      ENDIF
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF
    
    IF(diagnostics1) THEN
      CALL writestring(diagnostic_output_type,"",err,error,*999)
      CALL write_string(diagnostic_output_type,"Coordinate system metrics:",err,error,*999)
      CALL write_string_value(diagnostic_output_type,"  Coordinate system type = ",trim(coordinate_system_type_string( &
        & coordinate_system%TYPE)),err,error,*999)
      CALL write_string_value(diagnostic_output_type,"  Number of X dimensions = ",metrics%NUMBER_OF_X_DIMENSIONS,err,error,*999)
      CALL write_string_value(diagnostic_output_type,"  Number of Xi dimensions = ",metrics%NUMBER_OF_XI_DIMENSIONS,err,error,*999)
      CALL write_string(diagnostic_output_type,"  Location of metrics:",err,error,*999)
      CALL write_string_vector(diagnostic_output_type,1,1,metrics%NUMBER_OF_X_DIMENSIONS,3,3,interpolated_point%VALUES(:,1), &
        & '("    X           :",3(X,E13.6))','(17X,3(X,E13.6))',err,error,*999)      
      CALL write_string(diagnostic_output_type,"  Derivative of X wrt Xi:",err,error,*999)
      CALL write_string_matrix(diagnostic_output_type,1,1,metrics%NUMBER_OF_X_DIMENSIONS,1,1,metrics%NUMBER_OF_XI_DIMENSIONS, &
        & 3,3,metrics%DX_DXI,write_string_matrix_name_and_indices,'("    dX_dXi','(",I1,",:)',' :",3(X,E13.6))', &
        & '(17X,3(X,E13.6))',err,error,*999)
      IF(metrics%NUMBER_OF_X_DIMENSIONS/=metrics%NUMBER_OF_XI_DIMENSIONS) THEN
        CALL write_string(diagnostic_output_type,"  Constructed derivative of X wrt Xi:",err,error,*999)
        SELECT CASE(metrics%NUMBER_OF_XI_DIMENSIONS)
        CASE(1)
          !Line in space
          SELECT CASE(metrics%NUMBER_OF_X_DIMENSIONS)
          CASE(2)
            CALL write_string_vector(diagnostic_output_type,1,1,metrics%NUMBER_OF_X_DIMENSIONS,3,3,dx_dxi2, &
              & '("    dX_dXi(:,2) :",3(X,E13.6))','(17X,3(X,E13.6))',err,error,*999)      
          CASE(3)
            CALL write_string_vector(diagnostic_output_type,1,1,metrics%NUMBER_OF_X_DIMENSIONS,3,3,dx_dxi2, &
              & '("    dX_dXi(:,2) :",3(X,E13.6))','(17X,3(X,E13.6))',err,error,*999)      
            CALL write_string_vector(diagnostic_output_type,1,1,metrics%NUMBER_OF_X_DIMENSIONS,3,3,dx_dxi3, &
              & '("    dX_dXi(:,3) :",3(X,E13.6))','(17X,3(X,E13.6))',err,error,*999)      
          CASE DEFAULT
            CALL flagerror("Invalid embedding of a line in space.",err,error,*999)
          END SELECT
        CASE(2)
          !Surface in space
          SELECT CASE(metrics%NUMBER_OF_X_DIMENSIONS)
          CASE(3)
            CALL write_string_vector(diagnostic_output_type,1,1,metrics%NUMBER_OF_X_DIMENSIONS,3,3,dx_dxi3, &
              & '("    dX_dXi(:,3) :",3(X,E13.6))','(17X,3(X,E13.6))',err,error,*999)      
          CASE DEFAULT
            CALL flagerror("Invalid embedding of a surface in space.",err,error,*999)
          END SELECT
        CASE DEFAULT
          CALL flagerror("Invalid embedding in space.",err,error,*999)
        END SELECT
      ENDIF
      CALL write_string_value(diagnostic_output_type,"  det dX_dXi    = ",det_dx_dxi,err,error,*999)
      CALL write_string(diagnostic_output_type,"  Derivative of Xi wrt X:",err,error,*999)
      CALL write_string_matrix(diagnostic_output_type,1,1,metrics%NUMBER_OF_XI_DIMENSIONS,1,1,metrics%NUMBER_OF_X_DIMENSIONS, &
        & 3,3,metrics%DXI_DX,write_string_matrix_name_and_indices,'("    dXi_dX','(",I1,",:)',' :",3(X,E13.6))', &
        & '(17X,3(X,E13.6))',err,error,*999)
      CALL write_string(diagnostic_output_type,"  Covariant metric tensor:",err,error,*999)
      CALL write_string_matrix(diagnostic_output_type,1,1,metrics%NUMBER_OF_XI_DIMENSIONS,1,1,metrics%NUMBER_OF_XI_DIMENSIONS, &
        & 3,3,metrics%GL,write_string_matrix_name_and_indices,'("    GL','(",I1,",:)','     :",3(X,E13.6))','(17X,3(X,E13.6))', &
        & err,error,*999)      
      CALL write_string(diagnostic_output_type,"  Contravariant metric tensor:",err,error,*999)
      CALL write_string_matrix(diagnostic_output_type,1,1,metrics%NUMBER_OF_XI_DIMENSIONS,1,1,metrics%NUMBER_OF_XI_DIMENSIONS, &
        & 3,3,metrics%GU,write_string_matrix_name_and_indices,'("    GU','(",I1,",:)','     :",3(X,E13.6))','(17X,3(X,E13.6))', &
        & err,error,*999)      
      CALL write_string_value(diagnostic_output_type,"  Jacobian type = ",metrics%JACOBIAN_TYPE,err,error,*999)
      CALL write_string_value(diagnostic_output_type,"  Jacobian      = ",metrics%JACOBIAN,err,error,*999)
    ENDIF
    
    exits("COORDINATE_METRICS_CALCULATE")
    RETURN
999 errorsexits("COORDINATE_METRICS_CALCULATE",err,error)
    RETURN 1
  END SUBROUTINE coordinate_metrics_calculate

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_system_normal_calculate(COORDINATE_SYSTEM,REVERSE,X,N,ERR,ERROR,*)

    !Argument variables
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    LOGICAL, INTENT(IN) :: REVERSE
    REAL(DP), INTENT(IN) :: X(:,:)
    REAL(DP), INTENT(OUT) :: N(3)
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables
    INTEGER(INTG) :: NUMBER_OF_X_DIMENSIONS,d_s1,d_s2,d2_s1
    REAL(DP) :: LENGTH,R,TANGENT1(3),TANGENT2(3)
    TYPE(varying_string) :: LOCAL_ERROR

    enters("COORDINATE_SYSTEM_NORMAL_CALCULATE",err,error,*999)

    IF(ASSOCIATED(coordinate_system)) THEN
      IF(coordinate_system%COORDINATE_SYSTEM_FINISHED) THEN
        CALL flagerror("Coordinate system has been finished.",err,error,*999)
      ELSE
        number_of_x_dimensions=coordinate_system%NUMBER_OF_DIMENSIONS
        d_s1=partial_derivative_first_derivative_map(1)
        d_s2=partial_derivative_first_derivative_map(2)
        d2_s1=partial_derivative_second_derivative_map(1)
        SELECT CASE(coordinate_system%TYPE)
        CASE(coordinate_rectangular_cartesian_type)
          IF(number_of_x_dimensions==2) THEN
            tangent1(1)=x(1,d_s1)
            tangent1(2)=x(2,d_s1)
          ELSE IF(number_of_x_dimensions==3) THEN
            tangent1(1)=x(1,d_s1)
            tangent1(2)=x(2,d_s1)
            tangent1(3)=x(3,d_s1)
            tangent2(1)=x(1,d_s2)
            tangent2(2)=x(2,d_s2)
            tangent2(3)=x(3,d_s2)
          ELSE
            local_error=trim(number_to_vstring(number_of_x_dimensions,"*",err,error))// &
              & " is an invalid number of dimensions to calculate a normal from in a rectangular cartesian coordinate system."
            CALL flagerror(local_error,err,error,*999)
          ENDIF
        CASE(coordinate_cylindrical_polar_type)
          r=x(1,1)
          IF(number_of_x_dimensions==2) THEN
            tangent1(1)=x(1,d_s1)*cos(x(1,d_s1))-r*sin(x(1,d_s1))*x(2,d_s1)
            tangent1(2)=x(2,d_s1)*sin(x(1,d_s1))+r*cos(x(1,d_s1))*x(2,d_s1)
          ELSE IF(number_of_x_dimensions==3) THEN
            tangent1(1)=x(1,d_s1)*cos(x(1,d_s1))-r*sin(x(1,d_s1))*x(2,d_s1)
            tangent1(2)=x(2,d_s1)*sin(x(1,d_s1))+r*cos(x(1,d_s1))*x(2,d_s1)
            tangent1(3)=x(3,d_s1)
            tangent2(1)=x(1,d_s2)*cos(x(1,d_s1))-r*sin(x(1,d_s1))*x(2,d_s2)
            tangent2(2)=x(1,d_s2)*sin(x(1,d_s1))+r*cos(x(1,d_s1))*x(2,d_s2)
            tangent2(3)=x(3,d_s2)
           ELSE
            local_error=trim(number_to_vstring(number_of_x_dimensions,"*",err,error))// &
              & " is an invalid number of dimensions to calculate a normal from in a rectangular cartesian coordinate system."
            CALL flagerror(local_error,err,error,*999)
          ENDIF          
        CASE(coordinate_spherical_polar_type)
          r=x(1,1)
          tangent1(1)=x(1,d_s1)*cos(x(1,d2_s1))*cos(x(1,d_s1))- &
            &                 r*sin(x(1,d2_s1))*cos(x(1,d_s1))*x(3,d_s1)- &
            &                 r*cos(x(1,d2_s1))*sin(x(1,d_s1))*x(2,d_s1)
          tangent1(2)=x(1,d_s1)*cos(x(1,d2_s1))*sin(x(1,d_s1))- &
            &                 r*sin(x(1,d2_s1))*sin(x(1,d_s1))*x(3,d_s1)+ &
            &                 r*cos(x(1,d2_s1))*cos(x(1,d_s1))*x(2,d_s1)
          tangent1(3)=x(1,d_s1)*sin(x(1,d2_s1))+r*cos(x(1,d2_s1))*x(3,d_s1)
          tangent2(1)=x(1,d_s2)*cos(x(1,d2_s1))*cos(x(1,d_s1))- &
            &                 r*sin(x(1,d2_s1))*cos(x(1,d_s1))*x(3,d_s2)- &
            &                 r*cos(x(1,d2_s1))*sin(x(1,d_s1))*x(2,d_s2)
          tangent2(2)=x(1,d_s2)*cos(x(1,d2_s1))*sin(x(1,d_s1))- &
            &                 r*sin(x(1,d2_s1))*sin(x(1,d_s1))*x(3,d_s2)+ &
            &                 r*cos(x(1,d2_s1))*cos(x(1,d_s1))*x(2,d_s2)
          tangent2(3)=x(1,d_s2)*sin(x(1,d2_s1))+r*cos(x(1,d2_s1))*x(3,d_s2)
        CASE(coordinate_prolate_spheroidal_type)
          CALL flagerror("Not implemented.",err,error,*999)
        CASE(coordinate_oblate_spheroidal_type)
          CALL flagerror("Not implemented.",err,error,*999)
        CASE DEFAULT
          local_error="The coordinate system type of "//trim(number_to_vstring(coordinate_system%TYPE,"*",err,error))// &
            & " is invalid."
          CALL flagerror(local_error,err,error,*999)
        END SELECT
        IF(number_of_x_dimensions==2) THEN
          n(1)=-tangent1(2)
          n(2)=tangent1(1)
          length=sqrt(n(1)*n(1)+n(2)*n(2))
          IF(abs(length)<zero_tolerance) CALL flagerror("Zero normal vector length.",err,error,*999)
          IF(reverse) THEN
            n(1)=-n(1)/length
            n(2)=-n(2)/length
          ELSE            
            n(1)=n(1)/length
            n(2)=n(2)/length
          ENDIF
        ELSE
          n(1)=tangent1(2)*tangent2(3)-tangent1(3)*tangent2(2)
          n(2)=tangent1(3)*tangent2(1)-tangent1(1)*tangent2(3)
          n(3)=tangent1(1)*tangent2(2)-tangent1(2)*tangent2(1)
          length=sqrt(n(1)*n(1)+n(2)*n(2)+n(3)*n(3))
          IF(reverse) THEN
            n(1)=-n(1)/length
            n(2)=-n(2)/length
            n(3)=-n(3)/length
          ELSE            
            n(1)=n(1)/length
            n(2)=n(2)/length
            n(3)=n(3)/length
          ENDIF
        ENDIF        
      ENDIF
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF

    IF(diagnostics1) THEN
      CALL write_string(diagnostic_output_type,"Coordinate system metrics:",err,error,*999)
      CALL write_string_value(diagnostic_output_type,"  Coordinate system type = ",trim(coordinate_system_type_string( &
        & coordinate_system%TYPE)),err,error,*999)
      CALL write_string_value(diagnostic_output_type,"  Number of X dimensions = ",number_of_x_dimensions,err,error,*999)
      CALL write_string_vector(diagnostic_output_type,1,1,number_of_x_dimensions,3,3,x(:,1),'("  X         :",3(X,E13.6))', &
        & '(13X,3(X,E13.6))',err,error,*999)      
      CALL write_string_vector(diagnostic_output_type,1,1,number_of_x_dimensions,3,3,tangent1,'("  Tangent 1 :",3(X,E13.6))', &
        & '(13X,3(X,E13.6))',err,error,*999)
      IF(number_of_x_dimensions==3) THEN
        CALL write_string_vector(diagnostic_output_type,1,1,number_of_x_dimensions,3,3,tangent2,'("  Tangent 2 :",3(X,E13.6))', &
          & '(13X,3(X,E13.6))',err,error,*999)
      ENDIF
      CALL write_string_vector(diagnostic_output_type,1,1,number_of_x_dimensions,3,3,n,'("  Normal    :",3(X,E13.6))', &
        & '(13X,3(X,E13.6))',err,error,*999)            
    ENDIF
    
    exits("COORDINATE_SYSTEM_NORMAL_CALCULATE")
    RETURN
999 errorsexits("COORDINATE_SYSTEM_NORMAL_CALCULATE",err,error)
    RETURN 1
  END SUBROUTINE coordinate_system_normal_calculate

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_system_dimension_get(COORDINATE_SYSTEM,NUMBER_OF_DIMENSIONS,ERR,ERROR,*)

    !Argument variables
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    INTEGER(INTG), INTENT(OUT) :: NUMBER_OF_DIMENSIONS
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables

    enters("COORDINATE_SYSTEM_DIMENSION_GET",err,error,*999)

    IF(ASSOCIATED(coordinate_system)) THEN
      IF(coordinate_system%COORDINATE_SYSTEM_FINISHED) THEN
        number_of_dimensions=coordinate_system%NUMBER_OF_DIMENSIONS
      ELSE
        CALL flagerror("Coordinate system has not been finished.",err,error,*999)
      ENDIF
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF
   
    exits("COORDINATE_SYSTEM_DIMENSION_GET")
    RETURN
999 errorsexits("COORDINATE_SYSTEM_DIMENSION_GET",err,error)
    RETURN 1

  END SUBROUTINE coordinate_system_dimension_get

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_system_finalise(COORDINATE_SYSTEM,ERR,ERROR,*)

    !Argument variables
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables

    enters("COORDINATE_SYSTEM_FINALISE",err,error,*999)

    IF(ASSOCIATED(coordinate_system)) THEN
      DEALLOCATE(coordinate_system)
    ENDIF
   
    exits("COORDINATE_SYSTEM_FINALISE")
    RETURN
999 errorsexits("COORDINATE_SYSTEM_FINALISE",err,error)
    RETURN 1

  END SUBROUTINE coordinate_system_finalise

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_system_focus_get(COORDINATE_SYSTEM,FOCUS,ERR,ERROR,*)

    !Argument variables
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    REAL(DP), INTENT(OUT) :: FOCUS
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables

    enters("COORDINATE_SYSTEM_FOCUS_GET",err,error,*999)

    IF(ASSOCIATED(coordinate_system)) THEN
      IF(coordinate_system%COORDINATE_SYSTEM_FINISHED) THEN
        SELECT CASE(coordinate_system%TYPE)
        CASE(coordinate_prolate_spheroidal_type,coordinate_oblate_spheroidal_type)
          focus=coordinate_system%FOCUS
        CASE DEFAULT
          CALL flagerror("No focus defined for this coordinate system type.",err,error,*999)
        END SELECT
      ELSE
        CALL flagerror("Coordinate system has not been finished.",err,error,*999)
      ENDIF
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF
    
    exits("COORDINATE_SYSTEM_FOCUS_GET")
    RETURN
999 errorsexits("COORDINATE_SYSTEM_FOCUS_GET",err,error)
    RETURN 1
    
  END SUBROUTINE coordinate_system_focus_get

  !
  !================================================================================================================================
  !


  SUBROUTINE coordinates_radialinterpolationtypeget(coordinateSystem,radialInterpolationType,err,error,*)

    !Argument variables
    TYPE(coordinate_system_type), POINTER :: coordinateSystem
    INTEGER(INTG), INTENT(OUT) :: radialInterpolationType
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables
    
    enters("Coordinates_RadialInterpolationTypeGet",err,error,*999)

    IF(ASSOCIATED(coordinatesystem)) THEN
      IF(coordinatesystem%COORDINATE_SYSTEM_FINISHED) THEN
        SELECT CASE(coordinatesystem%TYPE)
        CASE(coordinate_cylindrical_polar_type,coordinate_spherical_polar_type)
          radialinterpolationtype=coordinatesystem%RADIAL_INTERPOLATION_TYPE
        CASE DEFAULT
          CALL flagerror("No radial interpolation type defined for this coordinate system interpolation.",err,error,*999)
        END SELECT
      ELSE
        CALL flagerror("Coordinate system has not been finished.",err,error,*999)
      ENDIF
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF
    
    exits("Coordinates_RadialInterpolationTypeGet")
    RETURN
999 errorsexits("Coordinates_RadialInterpolationTypeGet",err,error)
    RETURN 1
    
  END SUBROUTINE coordinates_radialinterpolationtypeget

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_system_type_get(COORDINATE_SYSTEM,SYSTEM_TYPE,ERR,ERROR,*)

    !Argument variables
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    INTEGER(INTG), INTENT(OUT) :: SYSTEM_TYPE
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables

    enters("COORDINATE_SYSTEM_TYPE_GET",err,error,*999)

    IF(ASSOCIATED(coordinate_system)) THEN
      IF(coordinate_system%COORDINATE_SYSTEM_FINISHED) THEN
        system_type=coordinate_system%TYPE
      ELSE
        CALL flagerror("Coordinate system has not been finished.",err,error,*999)
      ENDIF
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF
    
    exits("COORDINATE_SYSTEM_TYPE_GET")
    RETURN
999 errorsexits("COORDINATE_SYSTEM_TYPE_GET",err,error)
    RETURN 1

  END SUBROUTINE coordinate_system_type_get

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_system_dimension_set(COORDINATE_SYSTEM,DIMENSION,ERR,ERROR,*)

    !Argument variables
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    INTEGER(INTG), INTENT(IN) :: DIMENSION
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables

    enters("COORDINATE_SYSTEM_DIMENSION_SET",err,error,*999)

    IF(ASSOCIATED(coordinate_system)) THEN
      IF(coordinate_system%COORDINATE_SYSTEM_FINISHED) THEN
        CALL flagerror("Coordinate system has been finished.",err,error,*999)
      ELSE
        SELECT CASE(coordinate_system%TYPE)
        CASE(coordinate_rectangular_cartesian_type)
          IF(dimension>=1.AND.dimension<=3) THEN
            coordinate_system%NUMBER_OF_DIMENSIONS=dimension
          ELSE
            CALL flagerror("Invalid number of dimensions.",err,error,*999)
          ENDIF
        CASE(coordinate_cylindrical_polar_type)
          IF(dimension>=2.AND.dimension<=3) THEN
            coordinate_system%NUMBER_OF_DIMENSIONS=dimension
          ELSE
            CALL flagerror("Invalid number of dimensions.",err,error,*999)
          ENDIF
        CASE(coordinate_spherical_polar_type)
          IF(dimension==3) THEN
            coordinate_system%NUMBER_OF_DIMENSIONS=dimension
          ELSE
            CALL flagerror("Invalid number of dimensions.",err,error,*999)
          ENDIF
        CASE(coordinate_prolate_spheroidal_type)
          IF(dimension==3) THEN
            coordinate_system%NUMBER_OF_DIMENSIONS=dimension
          ELSE
            CALL flagerror("Invalid number of dimensions.",err,error,*999)
          ENDIF
        CASE(coordinate_oblate_spheroidal_type)
          IF(dimension==3) THEN
            coordinate_system%NUMBER_OF_DIMENSIONS=dimension
          ELSE
            CALL flagerror("Invalid number of dimensions.",err,error,*999)
          ENDIF
        CASE DEFAULT
          CALL flagerror("Invalid coordinate system type.",err,error,*999)
        END SELECT
      ENDIF
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF
    
    exits("COORDINATE_SYSTEM_DIMENSION_SET")
    RETURN
999 errorsexits("COORDINATE_SYSTEM_DIMENSION_SET",err,error)
    RETURN 1
  END SUBROUTINE coordinate_system_dimension_set

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_system_focus_set(COORDINATE_SYSTEM,FOCUS,ERR,ERROR,*)

    !Argument variables
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    REAL(DP), INTENT(IN) :: FOCUS
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables

    enters("COORDINATE_SYSTEM_FOCUS_SET",err,error,*999)

    IF(ASSOCIATED(coordinate_system)) THEN
      IF(coordinate_system%COORDINATE_SYSTEM_FINISHED) THEN
        CALL flagerror("Coordinate system has been finished.",err,error,*999)
      ELSE
        SELECT CASE(coordinate_system%TYPE)
        CASE(coordinate_prolate_spheroidal_type)
          IF(focus>zero_tolerance) THEN
            coordinate_system%FOCUS=focus
          ELSE
            CALL flagerror("Focus is less than zero.",err,error,*999)
          ENDIF
        CASE(coordinate_oblate_spheroidal_type)
          IF(focus>zero_tolerance) THEN
            coordinate_system%FOCUS=focus
          ELSE
            CALL flagerror("Focus is less than zero.",err,error,*999)
          ENDIF
        CASE DEFAULT
          CALL flagerror("Invalid coordinate system type.",err,error,*999)
        END SELECT
      ENDIF
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF
      
    exits("COORDINATE_SYSTEM_FOCUS_SET")
    RETURN
999 errorsexits("COORDINATE_SYSTEM_FOCUS_SET",err,error)
    RETURN 1
  END SUBROUTINE coordinate_system_focus_set

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinates_radialinterpolationtypeset(coordinateSystem,radialInterpolationType,err,error,*)

    !Argument variables
    TYPE(coordinate_system_type), POINTER :: coordinateSystem
    INTEGER(INTG), INTENT(IN) :: radialInterpolationType
    INTEGER(INTG), INTENT(OUT) :: err
    TYPE(varying_string), INTENT(OUT) :: error
    !Local Variables
    TYPE(varying_string) :: localError

    enters("Coordinates_RadialInterpolationTypeSet",err,error,*999)

    IF(ASSOCIATED(coordinatesystem)) THEN
      IF(coordinatesystem%COORDINATE_SYSTEM_FINISHED) THEN
        CALL flagerror("Coordinate system has been finished.",err,error,*999)
      ELSE
        SELECT CASE(coordinatesystem%TYPE)
        CASE(coordinate_rectangular_cartesian_type)
          SELECT CASE(radialinterpolationtype)
          CASE(coordinate_no_radial_interpolation_type)
            coordinatesystem%RADIAL_INTERPOLATION_TYPE=coordinate_no_radial_interpolation_type
          CASE DEFAULT
            localerror="The radial interpolation type of "//trim(number_to_vstring(radialinterpolationtype,"*",err,error))// &
              & " is invalid for a rectangular cartesian coordinate system."
            CALL flagerror(localerror,err,error,*999)
          END SELECT
        CASE(coordinate_cylindrical_polar_type,coordinate_spherical_polar_type)
          SELECT CASE(radialinterpolationtype)
          CASE(coordinate_radial_interpolation_type)
            coordinatesystem%RADIAL_INTERPOLATION_TYPE=coordinate_radial_interpolation_type
          CASE(coordinate_radial_squared_interpolation_type)
            coordinatesystem%RADIAL_INTERPOLATION_TYPE=coordinate_radial_squared_interpolation_type
          CASE DEFAULT
            localerror="The radial interpolation type of "//trim(number_to_vstring(radialinterpolationtype,"*",err,error))// &
              & " is invalid for a cylindrical/spherical coordinate system."
            CALL flagerror(localerror,err,error,*999)
          END SELECT
        CASE(coordinate_prolate_spheroidal_type)
          SELECT CASE(radialinterpolationtype)
          CASE(coordinate_radial_interpolation_type)
            coordinatesystem%RADIAL_INTERPOLATION_TYPE=coordinate_radial_interpolation_type
          CASE(coordinate_radial_squared_interpolation_type)
            coordinatesystem%RADIAL_INTERPOLATION_TYPE=coordinate_radial_squared_interpolation_type
          CASE(coordinate_radial_cubed_interpolation_type)
            coordinatesystem%RADIAL_INTERPOLATION_TYPE=coordinate_radial_cubed_interpolation_type
          CASE DEFAULT
            localerror="The radial interpolation type of "//trim(numbertovstring(radialinterpolationtype,"*",err,error))// &
              & " is invalid for a prolate spheroidal coordinate system."
            CALL flagerror(localerror,err,error,*999)
          END SELECT
        CASE(coordinate_oblate_spheroidal_type)
          CALL flagerror("Not implemented.",err,error,*999)
        CASE DEFAULT
          CALL flagerror("Invalid coordinate system type.",err,error,*999)
        END SELECT
      ENDIF
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF
    
    exits("Coordinates_RadialInterpolationTypeSet")
    RETURN
999 errorsexits("Coordinates_RadialInterpolationTypeSet",err,error)
    RETURN 1
  END SUBROUTINE coordinates_radialinterpolationtypeset

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_system_type_set(COORDINATE_SYSTEM,TYPE,ERR,ERROR,*)

    !Argument variables
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    INTEGER(INTG), INTENT(IN) :: TYPE
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables

    enters("COORDINATE_SYSTEM_TYPE_SET",err,error,*999)

    IF(ASSOCIATED(coordinate_system)) THEN
      IF(coordinate_system%COORDINATE_SYSTEM_FINISHED) THEN
        CALL flagerror("Coordinate system has been finished.",err,error,*999)
      ELSE
        SELECT CASE(type)
        CASE(coordinate_rectangular_cartesian_type)
          coordinate_system%TYPE=coordinate_rectangular_cartesian_type
        CASE(coordinate_cylindrical_polar_type)
          coordinate_system%TYPE=coordinate_cylindrical_polar_type
        CASE(coordinate_spherical_polar_type)
          coordinate_system%TYPE=coordinate_spherical_polar_type
        CASE(coordinate_prolate_spheroidal_type)
          coordinate_system%TYPE=coordinate_prolate_spheroidal_type
        CASE(coordinate_oblate_spheroidal_type)
          coordinate_system%TYPE=coordinate_oblate_spheroidal_type
        CASE DEFAULT
          CALL flagerror("Invalid coordinate system type.",err,error,*999)
        END SELECT
      ENDIF
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF
    
    exits("COORDINATE_SYSTEM_TYPE_SET")
    RETURN
999 errorsexits("COORDINATE_SYSTEM_TYPE_SET",err,error)
    RETURN 1
  END SUBROUTINE coordinate_system_type_set

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_system_origin_get(COORDINATE_SYSTEM,ORIGIN,ERR,ERROR,*)

    !Argument variables
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    REAL(DP), INTENT(OUT) :: ORIGIN(:)
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables

    enters("COORDINATE_SYSTEM_ORIGIN_GET",err,error,*999)

    IF(ASSOCIATED(coordinate_system)) THEN
      IF(coordinate_system%COORDINATE_SYSTEM_FINISHED) THEN
        IF(SIZE(origin)>=3) THEN
          origin(1:3)=coordinate_system%ORIGIN
        ELSE
          CALL flagerror("The origin must have >= 3 components.",err,error,*999)
        ENDIF
      ELSE
        CALL flagerror("Coordinate system has not been finished.",err,error,*999)
      ENDIF
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF
    
    exits("COORDINATE_SYSTEM_ORIGIN_GET")
    RETURN
999 errorsexits("COORDINATE_SYSTEM_ORIGIN_GET",err,error)
    RETURN 1
    
  END SUBROUTINE coordinate_system_origin_get

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_system_origin_set(COORDINATE_SYSTEM,ORIGIN,ERR,ERROR,*)

    !Argument variables
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    REAL(DP), INTENT(IN) :: ORIGIN(:)
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables

    enters("COORDINATE_SYSTEM_ORIGIN_SET",err,error,*999)

    IF(ASSOCIATED(coordinate_system)) THEN
      IF(coordinate_system%COORDINATE_SYSTEM_FINISHED) THEN
        CALL flagerror("Coordinate system has been finished.",err,error,*999)
      ELSE
        IF(SIZE(origin)==3) THEN
          coordinate_system%ORIGIN=origin
        ELSE
          CALL flagerror("The origin must have exactly 3 components.",err,error,*999)
        ENDIF
      ENDIF
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF
    
    exits("COORDINATE_SYSTEM_ORIGIN_SET")
    RETURN
999 errorsexits("COORDINATE_SYSTEM_ORIGIN_SET",err,error)
    RETURN 1
  END SUBROUTINE coordinate_system_origin_set

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_system_orientation_get(COORDINATE_SYSTEM,ORIENTATION,ERR,ERROR,*)

    !Argument variables
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    REAL(DP), INTENT(OUT) :: ORIENTATION(:,:)
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables

    enters("COORDINATE_SYSTEM_ORIENTATION_GET",err,error,*999)

    IF(ASSOCIATED(coordinate_system)) THEN
      IF(coordinate_system%COORDINATE_SYSTEM_FINISHED) THEN
        IF(SIZE(orientation,1)>=3.AND.SIZE(orientation,2)>=3) THEN
          orientation(1:3,1:3)=coordinate_system%ORIENTATION
        ELSE
          CALL flagerror("The orientation matrix must have >= 3x3 components.",err,error,*999)
        ENDIF
      ELSE
         CALL flagerror("Coordinate system has not been finished.",err,error,*999)
       ENDIF
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF
    
    exits("COORDINATE_SYSTEM_ORIENTATION_GET")
    RETURN
999 errorsexits("COORDINATE_SYSTEM_ORIENTATION_GET",err,error)
    RETURN 1
  END SUBROUTINE coordinate_system_orientation_get
  
  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_system_orientation_set(COORDINATE_SYSTEM,ORIENTATION,ERR,ERROR,*)

    !Argument variables
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    REAL(DP), INTENT(IN) :: ORIENTATION(:,:)
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables

    enters("COORDINATE_SYSTEM_ORIENTATION_SET",err,error,*999)

    IF(ASSOCIATED(coordinate_system)) THEN
      IF(coordinate_system%COORDINATE_SYSTEM_FINISHED) THEN
        CALL flagerror("Coordinate system has been finished.",err,error,*999)
      ELSE
        IF(SIZE(orientation,1)==3.AND.SIZE(orientation,2)==3) THEN
!!TODO: \todo Check orientation matrix vectors are orthogonal to each other etc.
          coordinate_system%ORIENTATION=orientation
        ELSE
          CALL flagerror("The orientation matrix must have exactly 3x3 components.",err,error,*999)
        ENDIF
      ENDIF
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF
    
    exits("COORDINATE_SYSTEM_ORIENTATION_SET")
    RETURN
999 errorsexits("COORDINATE_SYSTEM_ORIENTATION_SET",err,error)
    RETURN 1
  END SUBROUTINE coordinate_system_orientation_set
  
  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_system_create_start(USER_NUMBER,COORDINATE_SYSTEM,ERR,ERROR,*)

    !Argument variables
    INTEGER(INTG), INTENT(IN) :: USER_NUMBER
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables
    INTEGER(INTG) :: coord_system_idx
    TYPE(coordinate_system_type), POINTER :: NEW_COORDINATE_SYSTEM
    TYPE(coordinate_system_ptr_type), POINTER :: NEW_COORDINATE_SYSTEMS(:)
    TYPE(varying_string) :: LOCAL_ERROR

    NULLIFY(new_coordinate_system)
    NULLIFY(new_coordinate_systems)

    enters("COORDINATE_SYSTEM_CREATE_START",err,error,*998)

    NULLIFY(new_coordinate_system)
    CALL coordinate_system_user_number_find(user_number,new_coordinate_system,err,error,*999)
    IF(ASSOCIATED(new_coordinate_system)) THEN
      local_error="Coordinate system number "//trim(number_to_vstring(user_number,"*",err,error))// &
        & " has already been created."
      CALL flagerror(local_error,err,error,*998)
    ELSE
      IF(ASSOCIATED(coordinate_system)) THEN
        CALL flagerror("Coordinate system is already associated.",err,error,*999)
      ELSE
        NULLIFY(new_coordinate_system)
        ALLOCATE(new_coordinate_system,stat=err)
        IF(err/=0) CALL flagerror("Could not allocate new coordinate system.",err,error,*999)
      
        new_coordinate_system%USER_NUMBER=user_number
        new_coordinate_system%COORDINATE_SYSTEM_FINISHED=.false.
        new_coordinate_system%TYPE=coordinate_rectangular_cartesian_type
        new_coordinate_system%RADIAL_INTERPOLATION_TYPE=coordinate_no_radial_interpolation_type
        new_coordinate_system%NUMBER_OF_DIMENSIONS=3
        new_coordinate_system%FOCUS=1.0_dp    
        new_coordinate_system%ORIGIN=(/0.0_dp,0.0_dp,0.0_dp/)
        new_coordinate_system%ORIENTATION=reshape(&
          & (/1.0_dp,0.0_dp,0.0_dp, &
          &   0.0_dp,1.0_dp,0.0_dp, &
          &   0.0_dp,0.0_dp,1.0_dp/), &
          & (/3,3/))
        
        ALLOCATE(new_coordinate_systems(coordinate_systems%NUMBER_OF_COORDINATE_SYSTEMS+1),stat=err)
        IF(err/=0) CALL flagerror("Could not allocate new coordinate systems.",err,error,*999)
        DO coord_system_idx=1,coordinate_systems%NUMBER_OF_COORDINATE_SYSTEMS
          new_coordinate_systems(coord_system_idx)%PTR=>coordinate_systems%COORDINATE_SYSTEMS(coord_system_idx)%PTR
        ENDDO !coord_system_idx
        new_coordinate_systems(coordinate_systems%NUMBER_OF_COORDINATE_SYSTEMS+1)%PTR=>new_coordinate_system
        DEALLOCATE(coordinate_systems%COORDINATE_SYSTEMS)
        coordinate_systems%COORDINATE_SYSTEMS=>new_coordinate_systems
        coordinate_systems%NUMBER_OF_COORDINATE_SYSTEMS=coordinate_systems%NUMBER_OF_COORDINATE_SYSTEMS+1
        
        coordinate_system=>new_coordinate_system
      ENDIF
    ENDIF
        
    exits("COORDINATE_SYSTEM_CREATE_START")
    RETURN
999 IF(ASSOCIATED(new_coordinate_system)) DEALLOCATE(new_coordinate_system)
    IF(ASSOCIATED(new_coordinate_systems)) DEALLOCATE(new_coordinate_systems)
    NULLIFY(coordinate_system)
998 errorsexits("COORDINATE_SYSTEM_CREATE_START",err,error)
    RETURN 1
  END SUBROUTINE coordinate_system_create_start

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_system_create_finish(COORDINATE_SYSTEM,ERR,ERROR,*)

    !Argument variables
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables
    INTEGER(INTG) :: coord_system_idx

    enters("COORDINATE_SYSTEM_CREATE_FINISH",err,error,*999)

    IF(ASSOCIATED(coordinate_system)) THEN
      coordinate_system%COORDINATE_SYSTEM_FINISHED=.true.
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF
    
    IF(diagnostics1) THEN
      CALL write_string_value(diagnostic_output_type,"Number of coordinate systems = ", &
        & coordinate_systems%NUMBER_OF_COORDINATE_SYSTEMS,err,error,*999)
      DO coord_system_idx=1,coordinate_systems%NUMBER_OF_COORDINATE_SYSTEMS
        CALL write_string_value(diagnostic_output_type,"  Coordinate system : ",coord_system_idx,err,error,*999)
        CALL write_string_value(diagnostic_output_type,"    Number = ", &
          & coordinate_systems%COORDINATE_SYSTEMS(coord_system_idx)%PTR%USER_NUMBER,err,error,*999)
        CALL write_string_value(diagnostic_output_type,"    Type = ", &
          & coordinate_system_type_string(coordinate_systems%COORDINATE_SYSTEMS(coord_system_idx)%PTR%TYPE),err,error,*999)
        CALL write_string_value(diagnostic_output_type,"    Number of dimensions = ", &
          & coordinate_systems%COORDINATE_SYSTEMS(coord_system_idx)%PTR%NUMBER_OF_DIMENSIONS,err,error,*999)
      ENDDO !coord_system_idx
    ENDIF
    
    exits("COORDINATE_SYSTEM_CREATE_FINISH")
    RETURN
999 errorsexits("COORDINATE_SYSTEM_CREATE_FINISH",err,error)
    RETURN 1
  END SUBROUTINE coordinate_system_create_finish

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_system_destroy(COORDINATE_SYSTEM,ERR,ERROR,*)

    !Argument variables
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables
    INTEGER(INTG) :: coord_system_no,new_coord_system_no
    LOGICAL :: FOUND
    TYPE(coordinate_system_ptr_type), POINTER :: NEW_COORDINATE_SYSTEMS(:)

    enters("COORDINATE_SYSTEM_DESTROY",err,error,*999)

    IF(ASSOCIATED(coordinate_system)) THEN
      IF(coordinate_system%USER_NUMBER==0) THEN
        CALL flagerror("Cannot destroy the world coordinate system.",err,error,*999)
      ELSE
        found=.false.
        new_coord_system_no=0
        ALLOCATE(new_coordinate_systems(coordinate_systems%NUMBER_OF_COORDINATE_SYSTEMS-1),stat=err)
        IF(err/=0) CALL flagerror("Could not allocate new coordianate systems.",err,error,*999)
        DO coord_system_no=1,coordinate_systems%NUMBER_OF_COORDINATE_SYSTEMS
          IF(coordinate_systems%COORDINATE_SYSTEMS(coord_system_no)%PTR%USER_NUMBER==coordinate_system%USER_NUMBER) THEN
            found=.true.
          ELSE
            new_coord_system_no=new_coord_system_no+1
            new_coordinate_systems(new_coord_system_no)%PTR=>coordinate_systems%COORDINATE_SYSTEMS(coord_system_no)%PTR
          ENDIF
        ENDDO !coord_system_no
        IF(found) THEN
          CALL coordinate_system_finalise(coordinate_system,err,error,*999)
          DEALLOCATE(coordinate_systems%COORDINATE_SYSTEMS)
          coordinate_systems%COORDINATE_SYSTEMS=>new_coordinate_systems
          coordinate_systems%NUMBER_OF_COORDINATE_SYSTEMS=coordinate_systems%NUMBER_OF_COORDINATE_SYSTEMS-1
        ELSE
          DEALLOCATE(new_coordinate_systems)
          CALL flagerror("Coordinate system number to destroy does not exist.",err,error,*999)
        ENDIF
      ENDIF
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF
      
    exits("COORDINATE_SYSTEM_DESTROY")
    RETURN
999 errorsexits("COORDINATE_SYSTEM_DESTROY",err,error)
    RETURN 1
  END SUBROUTINE coordinate_system_destroy

  !
  !================================================================================================================================
  !
  
  FUNCTION dxz_dp(COORDINATE_SYSTEM,I,X,ERR,ERROR)
  
    !Argument variables
    TYPE(coordinate_system_type), INTENT(IN) :: COORDINATE_SYSTEM
    INTEGER(INTG), INTENT(IN) :: I
    REAL(DP), INTENT(IN) :: X(:)
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Function variable
    REAL(DP) :: DXZ_DP(size(x,1))
    !Local variables
    REAL(DP) :: RD,FOCUS

    enters("DXZ_DP",err,error,*999)

    dxz_dp=0.0_dp

    IF(SIZE(x,1)<coordinate_system%NUMBER_OF_DIMENSIONS) &
      & CALL flagerror("Size of X is less than the number of dimensions", &
      & err,error,*999)
   
    SELECT CASE(coordinate_system%TYPE)
    CASE(coordinate_rectangular_cartesian_type)
      IF(i>0.AND.i<=coordinate_system%NUMBER_OF_DIMENSIONS) THEN
        dxz_dp(i)=1.0_dp
      ELSE
        CALL flagerror("Invalid i value",err,error,*999)
      ENDIF
    CASE(coordinate_cylindrical_polar_type)
      SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
      CASE(2)
        SELECT CASE(i)
        CASE(1)
          dxz_dp(1)=cos(x(2))
          dxz_dp(2)=-sin(x(2))/x(1)
        CASE(2)
          dxz_dp(1)=sin(x(2))
          dxz_dp(2)=cos(x(2))/x(1)
        CASE DEFAULT
          CALL flagerror("Invalid i value",err,error,*999)
        END SELECT
      CASE(3)
        SELECT CASE(i)
        CASE(1)
          dxz_dp(1)=cos(x(2))
          dxz_dp(2)=-sin(x(2))/x(1)
          dxz_dp(3)=0.0_dp
        CASE(2)
          dxz_dp(1)=sin(x(2))
          dxz_dp(2)=cos(x(2))/x(1)
          dxz_dp(3)=0.0_dp
        CASE(3)
          dxz_dp(1)=0.0_dp
          dxz_dp(2)=0.0_dp
          dxz_dp(3)=1.0_dp
        CASE DEFAULT
          CALL flagerror("Invalid i value",err,error,*999)
        END SELECT
      CASE DEFAULT
        CALL flagerror("Invalid number of coordinates",err,error,*999)
      END SELECT
    CASE(coordinate_spherical_polar_type)
      IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
        SELECT CASE(i)
        CASE(1)
          dxz_dp(1)=cos(x(2))*cos(x(3))
          dxz_dp(2)=-sin(x(2))/(x(1)*cos(x(3)))
          dxz_dp(3)=-cos(x(2))*sin(x(3))/x(1)
        CASE(2)
          dxz_dp(1)=sin(x(2))*cos(x(3))
          dxz_dp(2)=cos(x(2))/(x(1)*cos(x(3)))
          dxz_dp(3)=-sin(x(2))*sin(x(3))/x(1)
        CASE(3)
          dxz_dp(1)=sin(x(3))
          dxz_dp(2)=0.0_dp
          dxz_dp(3)=cos(x(3))/x(1)
        CASE DEFAULT
          CALL flagerror("Invalid i value",err,error,*999)
        END SELECT
      ELSE
        CALL flagerror("Invalid number of coordinates",err,error,*999)
      ENDIF
    CASE(coordinate_prolate_spheroidal_type)
      IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
        focus=coordinate_system%FOCUS
        rd=focus*(cosh(x(1))*cosh(x(1))-cos(x(2))*cos(x(2)))
        SELECT CASE(i)
        CASE(1)
          dxz_dp(1)=sinh(x(1))*cos(x(2))/rd
          dxz_dp(2)=-cosh(x(1))*sin(x(2))/rd
          dxz_dp(3)=0.0_dp
        CASE(2)
          dxz_dp(1)=cosh(x(1))*sin(x(2))*cos(x(3))/rd
          dxz_dp(2)=sinh(x(1))*cos(x(2))*cos(x(3))/rd
          dxz_dp(3)=-sin(x(3))/(focus*sinh(x(1))*sin(x(2)))
        CASE(3)
          dxz_dp(1)=cosh(x(1))*sin(x(2))*sin(x(3))/rd
          dxz_dp(2)=sinh(x(1))*cos(x(2))*sin(x(3))/rd
          dxz_dp(3)=cos(x(3))/(focus*sinh(x(1))*sin(x(2)))
        CASE DEFAULT
          CALL flagerror("Invalid i value",err,error,*999)
        END SELECT
      ELSE
        CALL flagerror("Invalid number of coordinates",err,error,*999)
      ENDIF
    CASE(coordinate_oblate_spheroidal_type)
      CALL flagerror("Not implemented",err,error,*999)
    CASE DEFAULT
      CALL flagerror("Invalid coordinate type",err,error,*999)
    END SELECT

    exits("DXZ_DP")
    RETURN
999 errorsexits("DXZ_DP",err,error)
    RETURN 
  END FUNCTION dxz_dp

  !
  !================================================================================================================================
  !

  !#### Generic-Function: D2ZX
  !###  Description:
  !###    Calculates D2Z(:)/DX(I)DX(J) at X(:), where Z(:) are rectangalar
  !###    Cartesian and X(I) and X(J) are curvilinear coordinates defined by 
  !###    COORDINATE_SYSTEM.
  !###  Child-functions: D2ZX_SP,D2ZX_SP

  !
  !================================================================================================================================
  !
  
  FUNCTION d2zx_dp(COORDINATE_SYSTEM,I,J,X,ERR,ERROR)
  
    !#### Function: D2ZX_DP
    !###  Type: REAL(DP)(SIZE(X,1))
    !###  Description:
    !###    Calculates D2Z(:)/DX(I)DX(J) at X(:), where Z(:) are rectangalar
    !###    Cartesian and X(I) and X(J) are curvilinear coordinates defined by 
    !###    COORDINATE_SYSTEM.
    !###  Parent-function: D2ZX
    
    !Argument variables
    TYPE(coordinate_system_type), INTENT(IN) :: COORDINATE_SYSTEM
    INTEGER(INTG), INTENT(IN) :: I,J
    REAL(DP), INTENT(IN) :: X(:)
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Function variable
    REAL(DP) :: D2ZX_DP(size(x,1))
    !Local variables
    REAL(DP) :: FOCUS

    enters("D2ZX_DP",err,error,*999)

    d2zx_dp=0.0_dp

    IF(SIZE(x,1)<coordinate_system%NUMBER_OF_DIMENSIONS) &
      & CALL flagerror("Size of X is less than the number of dimensions", &
      & err,error,*999)
   
    SELECT CASE(coordinate_system%TYPE)
    CASE(coordinate_rectangular_cartesian_type)
      d2zx_dp(1:coordinate_system%NUMBER_OF_DIMENSIONS)=0.0_dp
    CASE(coordinate_cylindrical_polar_type)
      SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
      CASE(2)
        SELECT CASE(i)
        CASE(1)
          SELECT CASE(j)
          CASE(1)
            d2zx_dp(1)=0.0_dp
            d2zx_dp(2)=0.0_dp
          CASE(2)
            d2zx_dp(1)=-sin(x(2))
            d2zx_dp(2)=cos(x(2))
          CASE DEFAULT
            CALL flagerror("Invalid j value",err,error,*999)
          END SELECT
        CASE(2)
          SELECT CASE(j)
          CASE(1)
            d2zx_dp(1)=-sin(x(2))
            d2zx_dp(2)=cos(x(2))
          CASE(2)
            d2zx_dp(1)=-x(1)*cos(x(2))
            d2zx_dp(2)=-x(1)*sin(x(2))
          CASE DEFAULT
            CALL flagerror("Invalid j value",err,error,*999)
          END SELECT
        CASE DEFAULT
          CALL flagerror("Invalid i value",err,error,*999)
        END SELECT
      CASE(3)
        SELECT CASE(i)
        CASE(1)
          SELECT CASE(j)
          CASE(1)
            d2zx_dp(1)=0.0_dp
            d2zx_dp(2)=0.0_dp
            d2zx_dp(3)=0.0_dp
          CASE(2)
            d2zx_dp(1)=-sin(x(2))
            d2zx_dp(2)=cos(x(2))
            d2zx_dp(3)=0.0_dp
          CASE(3)
            d2zx_dp(1)=0.0_dp
            d2zx_dp(2)=0.0_dp
            d2zx_dp(3)=0.0_dp
          CASE DEFAULT
            CALL flagerror("Invalid j value",err,error,*999)
          END SELECT
        CASE(2)
          SELECT CASE(j)
          CASE(1)
            d2zx_dp(1)=-sin(x(2))
            d2zx_dp(2)=cos(x(2))
            d2zx_dp(3)=0.0_dp
          CASE(2)
            d2zx_dp(1)=-x(1)*cos(x(2))
            d2zx_dp(2)=-x(1)*sin(x(2))
            d2zx_dp(3)=0.0_dp
          CASE(3)
            d2zx_dp(1)=0.0_dp
            d2zx_dp(2)=0.0_dp
            d2zx_dp(3)=0.0_dp
          CASE DEFAULT
            CALL flagerror("Invalid j value",err,error,*999)
          END SELECT
        CASE(3)
          SELECT CASE(j)
          CASE(1)
            d2zx_dp(1)=0.0_dp
            d2zx_dp(2)=0.0_dp
            d2zx_dp(3)=0.0_dp
          CASE(2)
            d2zx_dp(1)=0.0_dp
            d2zx_dp(2)=0.0_dp
            d2zx_dp(3)=0.0_dp
          CASE(3)
            d2zx_dp(1)=0.0_dp
            d2zx_dp(2)=0.0_dp
            d2zx_dp(3)=0.0_dp
          CASE DEFAULT
            CALL flagerror("Invalid j value",err,error,*999)
          END SELECT
        CASE DEFAULT
          CALL flagerror("Invalid i value",err,error,*999)
        END SELECT
      CASE DEFAULT
        CALL flagerror("Invalid number of coordinates",err,error,*999)
      END SELECT
    CASE(coordinate_spherical_polar_type)
      IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
        SELECT CASE(i)
        CASE(1)
          SELECT CASE(j)
          CASE(1)
            d2zx_dp(1)=0.0_dp
            d2zx_dp(2)=0.0_dp
            d2zx_dp(3)=0.0_dp
          CASE(2)
            d2zx_dp(1)=-sin(x(2))*cos(x(3))
            d2zx_dp(2)=cos(x(2))*cos(x(3))
            d2zx_dp(3)=0.0_dp
          CASE(3)
            d2zx_dp(1)=-cos(x(2))*sin(x(3))
            d2zx_dp(2)=-sin(x(2))*sin(x(3))
            d2zx_dp(3)=cos(x(3))
          CASE DEFAULT
            CALL flagerror("Invalid j value",err,error,*999)
          END SELECT
        CASE(2)
          SELECT CASE(j)
          CASE(1)
            d2zx_dp(1)=-sin(x(2))*cos(x(3))
            d2zx_dp(2)=cos(x(2))*cos(x(3))
            d2zx_dp(3)=0.0_dp
          CASE(2)
            d2zx_dp(1)=-x(1)*cos(x(2))*cos(x(3))
            d2zx_dp(2)=-x(1)*sin(x(2))*cos(x(3))
            d2zx_dp(3)=0.0_dp
          CASE(3)
            d2zx_dp(1)=x(1)*sin(x(2))*sin(x(3))
            d2zx_dp(2)=-x(1)*cos(x(2))*sin(x(3))
            d2zx_dp(3)=0.0_dp
          CASE DEFAULT
            CALL flagerror("Invalid j value",err,error,*999)
          END SELECT
        CASE(3)
          SELECT CASE(j)
          CASE(1)
            d2zx_dp(1)=-cos(x(2))*sin(x(3))
            d2zx_dp(2)=-sin(x(2))*sin(x(3))
            d2zx_dp(3)=cos(x(3))
          CASE(2)
            d2zx_dp(1)=x(1)*sin(x(2))*sin(x(3))
            d2zx_dp(2)=-x(1)*cos(x(2))*sin(x(3))
            d2zx_dp(3)=0.0_dp
          CASE(3)
            d2zx_dp(1)=-x(1)*cos(x(2))*cos(x(3))
            d2zx_dp(2)=-x(1)*sin(x(2))*cos(x(3))
            d2zx_dp(3)=-x(1)*sin(x(3))
          CASE DEFAULT
            CALL flagerror("Invalid j value",err,error,*999)
          END SELECT
        CASE DEFAULT
          CALL flagerror("Invalid i value",err,error,*999)
        END SELECT
      ELSE
        CALL flagerror("Invalid number of coordinates",err,error,*999)
      ENDIF
    CASE(coordinate_prolate_spheroidal_type)
      IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
        focus=coordinate_system%FOCUS
        SELECT CASE(i)
        CASE(1)
          SELECT CASE(j)
          CASE(1)
            d2zx_dp(1)=focus*cosh(x(1))*cos(x(2))          
            d2zx_dp(2)=focus*sinh(x(1))*sin(x(2))*cos(x(3))
            d2zx_dp(3)=focus*sinh(x(1))*sin(x(2))*sin(x(3))
          CASE(2)
            d2zx_dp(1)=-focus*sinh(x(1))*sin(x(2))
            d2zx_dp(2)=focus*cosh(x(1))*cos(x(2))*cos(x(3))
            d2zx_dp(3)=focus*cosh(x(1))*cos(x(2))*sin(x(3))
          CASE(3)
            d2zx_dp(1)=0.0_dp
            d2zx_dp(2)=-focus*cosh(x(1))*sin(x(2))*sin(x(3))
            d2zx_dp(3)=focus*cosh(x(1))*sin(x(2))*cos(x(3))
          CASE DEFAULT
            CALL flagerror("Invalid j value",err,error,*999)
          END SELECT
        CASE(2)
          SELECT CASE(j)
          CASE(1)
            d2zx_dp(1)=-focus*sinh(x(1))*sin(x(2))
            d2zx_dp(2)=focus*cosh(x(1))*cos(x(2))*cos(x(3))
            d2zx_dp(3)=focus*cosh(x(1))*cos(x(2))*sin(x(3))
          CASE(2)
            d2zx_dp(1)=-focus*cosh(x(1))*cos(x(2))
            d2zx_dp(2)=-focus*sinh(x(1))*sin(x(2))*cos(x(3))
            d2zx_dp(3)=-focus*sinh(x(1))*sin(x(2))*sin(x(3))
          CASE(3)
            d2zx_dp(1)=0.0_dp
            d2zx_dp(2)=-focus*sinh(x(1))*cos(x(2))*sin(x(3))
            d2zx_dp(3)=focus*sinh(x(1))*cos(x(2))*cos(x(3))
          CASE DEFAULT
            CALL flagerror("Invalid j value",err,error,*999)
          END SELECT
        CASE(3)
          SELECT CASE(j)
          CASE(1)
            d2zx_dp(1)=0.0_dp
            d2zx_dp(2)=-focus*cosh(x(1))*sin(x(2))*sin(x(3))
            d2zx_dp(3)=focus*cosh(x(1))*sin(x(2))*cos(x(3))
          CASE(2)
            d2zx_dp(1)=0.0_dp
            d2zx_dp(2)=-focus*sinh(x(1))*cos(x(2))*sin(x(3))
            d2zx_dp(3)=focus*sinh(x(1))*cos(x(2))*cos(x(3))
          CASE(3)
            d2zx_dp(1)=0.0_dp
            d2zx_dp(2)=-focus*sinh(x(1))*sin(x(2))*cos(x(3))
            d2zx_dp(3)=-focus*sinh(x(1))*sin(x(2))*sin(x(3))
          CASE DEFAULT
            CALL flagerror("Invalid j value",err,error,*999)
          END SELECT
        CASE DEFAULT
          CALL flagerror("Invalid i value",err,error,*999)
        END SELECT
      ELSE
        CALL flagerror("Invalid number of coordinates",err,error,*999)
      ENDIF
    CASE(coordinate_oblate_spheroidal_type)
      CALL flagerror("Not implemented",err,error,*999)
    CASE DEFAULT
      CALL flagerror("Invalid coordinate type",err,error,*999)
    END SELECT

    exits("D2ZX_DP")
    RETURN
999 errorsexits("D2ZX_DP",err,error)
    RETURN 
  END FUNCTION d2zx_dp

  !
  !================================================================================================================================
  !
  
  !#### Generic-Function: DZX
  !###  Description:
  !###    Calculates DZ(:)/DX(J) at X, where Z(:) are rectangalar
  !###    Cartesian and X(J) are curvilinear coordinates defined by 
  !###    COORDINATE_SYSTEM.
  !###  Child-functions: DZX_DP,DZX_SP

  !
  !================================================================================================================================
  !
  
  FUNCTION dzx_dp(COORDINATE_SYSTEM,I,X,ERR,ERROR)
  
    !#### Function: DZX_DP
    !###  Type: REAL(DP)(SIZE(X,1))
    !###  Description:
    !###    Calculates DZ(:)/DX(I) at X, where Z(:) are rectangalar
    !###    Cartesian and X(I) are curvilinear coordinates defined by 
    !###    COORDINATE_SYSTEM.
    !###  Parent-function: DZX
    
    !Argument variables
    TYPE(coordinate_system_type), INTENT(IN) :: COORDINATE_SYSTEM
    INTEGER(INTG), INTENT(IN) :: I
    REAL(DP), INTENT(IN) :: X(:)
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Function variable
    REAL(DP) :: DZX_DP(size(x,1))
    !Local variables
    REAL(DP) :: FOCUS

    enters("DZX_DP",err,error,*999)

    dzx_dp=0.0_dp

    IF(SIZE(x,1)<coordinate_system%NUMBER_OF_DIMENSIONS) &
      & CALL flagerror("Size of X is less than the number of dimensions", &
      & err,error,*999)
   
   SELECT CASE(coordinate_system%TYPE)
    CASE(coordinate_rectangular_cartesian_type)
      IF(i>0.AND.i<=coordinate_system%NUMBER_OF_DIMENSIONS) THEN
        dzx_dp(i)=1.0_dp
      ELSE
        CALL flagerror("Invalid i value",err,error,*999)
      ENDIF
    CASE(coordinate_cylindrical_polar_type)
      SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
      CASE(2)
        SELECT CASE(i)
        CASE(1)
          dzx_dp(1)=cos(x(2))
          dzx_dp(2)=sin(x(2))
        CASE(2)
          dzx_dp(1)=-x(1)*sin(x(2))
          dzx_dp(2)=x(1)*cos(x(2))
        CASE DEFAULT
          CALL flagerror("Invalid i value",err,error,*999)
        END SELECT
      CASE(3)
        SELECT CASE(i)
        CASE(1)
          dzx_dp(1)=cos(x(2))
          dzx_dp(2)=sin(x(2))
          dzx_dp(3)=0.0_dp
        CASE(2)
          dzx_dp(1)=-x(1)*sin(x(2))
          dzx_dp(2)=x(1)*cos(x(2))
          dzx_dp(3)=0.0_dp
        CASE(3)
          dzx_dp(1)=0.0_dp
          dzx_dp(2)=0.0_dp
          dzx_dp(3)=1.0_dp
        CASE DEFAULT
          CALL flagerror("Invalid i value",err,error,*999)
        END SELECT
      CASE DEFAULT
        CALL flagerror("Invalid number of coordinates",err,error,*999)
      END SELECT
    CASE(coordinate_spherical_polar_type)
      IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
        SELECT CASE(i)
        CASE(1)
          dzx_dp(1)=cos(x(2))*cos(x(3))
          dzx_dp(2)=sin(x(2))*cos(x(3))
          dzx_dp(3)=sin(x(3))
        CASE(2)
          dzx_dp(1)=-x(1)*sin(x(2))*cos(x(3))
          dzx_dp(2)=x(1)*cos(x(2))*cos(x(3))
          dzx_dp(3)=0.0_dp
        CASE(3)
          dzx_dp(1)=-x(1)*cos(x(2))*sin(x(3))
          dzx_dp(2)=-x(1)*sin(x(2))*sin(x(3))
          dzx_dp(3)=x(1)*cos(x(3))
        CASE DEFAULT
          CALL flagerror("Invalid i value",err,error,*999)
        END SELECT
      ELSE
        CALL flagerror("Invalid number of coordinates",err,error,*999)
      ENDIF
    CASE(coordinate_prolate_spheroidal_type)
      IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
        focus=coordinate_system%FOCUS
        SELECT CASE(i)
        CASE(1)
          dzx_dp(1)=focus*sinh(x(1))*cos(x(2))
          dzx_dp(2)=focus*cosh(x(1))*sin(x(2))*cos(x(3))
          dzx_dp(3)=focus*cosh(x(1))*sin(x(2))*sin(x(3))
        CASE(2)
          dzx_dp(1)=-focus*cosh(x(1))*sin(x(2))
          dzx_dp(2)=focus*sinh(x(1))*cos(x(2))*cos(x(3))
          dzx_dp(3)=focus*sinh(x(1))*cos(x(2))*sin(x(3))
        CASE(3)
          dzx_dp(1)=0.0_dp
          dzx_dp(2)=-focus*sinh(x(1))*sin(x(2))*sin(x(3))
          dzx_dp(3)=focus*sinh(x(1))*sin(x(2))*cos(x(3))
        CASE DEFAULT
          CALL flagerror("Invalid i value",err,error,*999)
        END SELECT
      ELSE
        CALL flagerror("Invalid number of coordinates",err,error,*999)
      ENDIF
    CASE(coordinate_oblate_spheroidal_type)
      IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
        focus=coordinate_system%FOCUS
        SELECT CASE(i)
        CASE(1)
          dzx_dp(1)=focus*sinh(x(1))*cos(x(2))*cos(x(3))
          dzx_dp(2)=focus*cosh(x(1))*sin(x(2))
          dzx_dp(3)=focus*sinh(x(1))*cos(x(2))*sin(x(3))
        CASE(2)
          dzx_dp(1)=-focus*cosh(x(1))*sin(x(2))*cos(x(3))
          dzx_dp(2)=focus*sinh(x(1))*cos(x(2))
          dzx_dp(3)=-focus*cosh(x(1))*sin(x(2))*sin(x(3))
        CASE(3)
          dzx_dp(1)=-focus*cosh(x(1))*cos(x(2))*sin(x(3))
          dzx_dp(2)=0.0_dp
          dzx_dp(3)=focus*cosh(x(1))*cos(x(2))*cos(x(3))
        CASE DEFAULT
          CALL flagerror("Invalid i value",err,error,*999)
        END SELECT
      ELSE
        CALL flagerror("Invalid number of coordinates",err,error,*999)
      ENDIF
    CASE DEFAULT
      CALL flagerror("Invalid coordinate type",err,error,*999)
    END SELECT

    exits("DZX_DP")
    RETURN
999 errorsexits("DZX_DP",err,error)
    RETURN 
  END FUNCTION dzx_dp

  !
  !================================================================================================================================
  !

  !!TODO:: CHANGE THIS TO A FUNCTION
  
  !#### Generic-subroutine: COORDINATE_DERIVATIVE_CONVERT_TO_RC
  !###  Description:
  !###    COORDINATE_DERIVATIVE_CONVERT_TO_RC performs a coordinate transformation from a
  !###    coordinate system identified by COORDINATE at the point X
  !###    with coordinates/derivatives X(nj,nu) to the point with 
  !###    coordinates/derivatives Z(nj) in rectangular cartesian coordinates
  !###  Child-subroutines: COORDINATE_DERIVATIVE_CONVERT_TO_RC_DP,COORDINATE_DERIVATIVE_CONVERT_TO_RC_SP

  !
  !================================================================================================================================
  !
  
  SUBROUTINE coordinate_derivative_convert_to_rc_dp(COORDINATE_SYSTEM,PART_DERIV_TYPE,X,Z,&
    & err,error,*)
  
    !#### Subroutine: COORDINATE_DERIVATIVE_CONVERT_TO_RC_DP
    !###  Description:
    !###    COORDINATE_DERIVATIVE_CONVERT_TO_RC_DP performs a coordinate transformation from a
    !###    coordinate system identified by COORDINATE_SYSTEM at the point X
    !###    with coordinates/derivatives X(nj,nu) to the point with 
    !###    coordinates/derivatives Z(nj) in rectangular cartesian coordinates
    !###    for double precision coordinates.
    !###  Parent-function: COORDINATE_DERIVATIVE_CONVERT_TO_RC
    
    !Argument variables
    TYPE(coordinate_system_type), INTENT(IN) :: COORDINATE_SYSTEM
    INTEGER(INTG), INTENT(IN) :: PART_DERIV_TYPE
    REAL(DP), INTENT(IN) :: X(:,:)
    REAL(DP), INTENT(OUT) :: Z(:)
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local variables
    REAL(DP) :: FOCUS
    
    enters("COORDINATE_DERIVATIVE_CONVERT_TO_RC_DP",err,error,*999)

!!TODO: change all second index X(:,?) numbers to their apropriate constant
!!as defined in constants e.g. X(1,2) == X(1,PART_DERIV_S1)
    
    IF(SIZE(x,1)<coordinate_system%NUMBER_OF_DIMENSIONS) &
      & CALL flagerror("Size of X is less than the number of dimensions", &
      & err,error,*999)
    
    IF(SIZE(x,1)==SIZE(z,1)) THEN
      SELECT CASE(coordinate_system%TYPE)
      CASE(coordinate_rectangular_cartesian_type)
        IF(SIZE(x,2)>=part_deriv_type) THEN
          z=x(:,part_deriv_type)
        ELSE
          CALL flagerror("Invalid derivative type",err,error,*999)
        ENDIF
      CASE(coordinate_cylindrical_polar_type)
        SELECT CASE(part_deriv_type)
        CASE(no_part_deriv)
          z=coordinate_convert_to_rc(coordinate_system,x(:,1),err,error)
          IF(err/=0) GOTO 999
        CASE(part_deriv_s1)
          IF(SIZE(x,2)>=2) THEN
            SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
            CASE(2)
              z(1)=cos(x(2,1))*x(1,2)-x(1,1)*sin(x(2,1))*x(2,2) !d(x)/d(s1)
              z(2)=sin(x(2,1))*x(1,2)+x(1,1)*cos(x(2,1))*x(2,2) !d(y)/d(s1)
            CASE(3)
              z(1)=cos(x(2,1))*x(1,2)-x(1,1)*sin(x(2,1))*x(2,2) !d(x)/d(s1)
              z(2)=sin(x(2,1))*x(1,2)+x(1,1)*cos(x(2,1))*x(2,2) !d(y)/d(s1)
              z(3)=x(3,2) !d(z)/d(s1)
            CASE DEFAULT
              CALL flagerror("Invalid number of coordinates",err,error,*999)
            END SELECT
          ELSE
            CALL flagerror("Not enough X derivatives supplied",err,error,*999)
          ENDIF
        CASE(part_deriv_s1_s1)
          CALL flagerror("Not implemented",err,error,*999)
        CASE(part_deriv_s2)
          IF(SIZE(x,2)>=4) THEN
            SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
            CASE(2)
              z(1)=cos(x(2,1))*x(1,4)-x(1,1)*sin(x(2,1))*x(2,4) !d(x)/d(s2)
              z(2)=sin(x(2,1))*x(1,4)+x(1,1)*cos(x(2,1))*x(2,4) !d(y)/d(s2)
            CASE(3)
              z(1)=cos(x(2,1))*x(1,4)-x(1,1)*sin(x(2,1))*x(2,4) !d(x)/d(s2)
              z(2)=sin(x(2,1))*x(1,4)+x(1,1)*cos(x(2,1))*x(2,4) !d(y)/d(s2)
              z(3)=x(3,4) !d(z)/d(s2)
            CASE DEFAULT
              CALL flagerror("Invalid number of coordinates",err,error,*999)
            END SELECT
          ELSE
            CALL flagerror("Not enough X derivatives supplied",err,error,*999)
          ENDIF
        CASE(part_deriv_s2_s2)
          CALL flagerror("Not implemented",err,error,*999)
        CASE(part_deriv_s1_s2)
          IF(SIZE(x,2)>=6) THEN
            SELECT CASE(SIZE(x,1))
            CASE(2)
              z(1)=cos(x(2,1))*x(1,6)-x(1,2)*sin(x(2,1))*x(2,4)-&
                & (x(1,4)*sin(x(2,1))*x(2,2)+x(1,1)*cos(x(2,1))*&
                & x(2,2)*x(2,4)+x(1,1)*sin(x(2,1))*x(2,6)) !d2(x)/d(s1)d(s2)
              z(2)=sin(x(2,1))*x(1,6)+x(1,2)*cos(x(2,1))*x(2,4)+&
                & (x(1,4)*cos(x(2,1))*x(2,2)-x(1,1)*sin(x(2,1))*&
                & x(2,2)*x(2,4)+x(1,1)*cos(x(2,1))*x(2,6)) !d2(y)/d(s1)d(s2)
            CASE(3)
              z(1)=cos(x(2,1))*x(1,6)-x(1,2)*sin(x(2,1))*x(2,4)-&
                & (x(1,4)*sin(x(2,1))*x(2,2)+x(1,1)*cos(x(2,1))*&
                & x(2,2)*x(2,4)+x(1,1)*sin(x(2,1))*x(2,6)) !d2(x)/d(s1)d(s2)
              z(2)=sin(x(2,1))*x(1,6)+x(1,2)*cos(x(2,1))*x(2,4)+&
                & (x(1,4)*cos(x(2,1))*x(2,2)-x(1,1)*sin(x(2,1))*&
                & x(2,2)*x(2,4)+x(1,1)*cos(x(2,1))*x(2,6)) !d2(y)/d(s1)d(s2)
              z(3)=x(3,6) !d2(z)/d(s1)d(s2)
            CASE DEFAULT
              CALL flagerror("Invalid number of coordinates",err,error,*999)
            END SELECT
          ELSE
            CALL flagerror("Not enough X derivatives supplied",err,error,*999)
          ENDIF
        CASE(part_deriv_s3)
          IF(SIZE(x,2)>=7) THEN
            SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
            CASE(2)
              z(1)=0.0_dp
              z(2)=0.0_dp
            CASE(3)
              z(1)=cos(x(2,1))*x(1,7)-x(1,1)*sin(x(2,1))*x(2,7) !d(x)/d(s3)
              z(2)=sin(x(2,1))*x(1,7)+x(1,1)*cos(x(2,1))*x(2,7) !d(y)/d(s3)
              z(3)=x(3,7) !d(z)/d(s3)
            CASE DEFAULT
              CALL flagerror("Invalid number of coordinates",err,error,*999)
            END SELECT
          ELSE
            CALL flagerror("Not enough X derivatives supplied",err,error,*999)
          ENDIF
        CASE(part_deriv_s3_s3)
          CALL flagerror("Not implemented",err,error,*999)
        CASE(part_deriv_s1_s3)
          IF(SIZE(x,2)>=9) THEN
            SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
            CASE(2)
              z(1)=0.0_dp
              z(2)=0.0_dp
            CASE(3)
              z(1)=cos(x(2,1))*x(1,9)-x(1,2)*sin(x(2,1))*x(2,7)-&
                & (x(1,7)*sin(x(2,1))*x(2,2)+x(1,1)*cos(x(2,1))*&
                & x(2,2)*x(2,7)+x(1,1)*sin(x(2,1))*x(2,9)) !d2(x)/d(s1)d(s3)
              z(2)=sin(x(2,1))*x(1,9)+x(1,2)*cos(x(2,1))*x(2,7)+&
                & (x(1,7)*cos(x(2,1))*x(2,2)-x(1,1)*sin(x(2,1))*&
                & x(2,2)*x(2,7)+x(1,1)*cos(x(2,1))*x(2,9)) !d2(y)/d(s1)d(s3)
              z(3)=x(3,9) !d2(z)/d(s1)d(s3)
            CASE DEFAULT
              CALL flagerror("Invalid number of coordinates",err,error,*999)
            END SELECT
          ELSE
            CALL flagerror("Not enough X derivatives supplied",err,error,*999)
          ENDIF
        CASE(part_deriv_s2_s3)
          IF(SIZE(x,2)>=10) THEN
            SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
            CASE(2)
              z(1)=0.0_dp
              z(2)=0.0_dp
            CASE(3)
              z(1)=cos(x(2,1))*x(1,10)-x(1,4)*sin(x(2,1))*x(2,7)-&
                & (x(1,7)*sin(x(2,1))*x(2,4)+x(1,1)*cos(x(2,1))*&
                & x(2,4)*x(2,7)+x(1,1)*sin(x(2,1))*x(2,10)) !d2(x)/d(s2)d(s3)
              z(2)=sin(x(2,1))*x(1,10)+x(1,4)*cos(x(2,1))*x(2,7)+&
                & (x(1,7)*cos(x(2,1))*x(2,4)-x(1,1)*sin(x(2,1))*&
                & x(2,4)*x(2,7)+x(1,1)*cos(x(2,1))*x(2,10)) !d2(y)/d(s2)d(s3)
              z(3)=x(3,10) !d2(z)/d(s2)d(s3)
            CASE DEFAULT
              CALL flagerror("Invalid number of coordinates",err,error,*999)
            END SELECT
          ELSE
            CALL flagerror("Not enough X derivatives supplied",err,error,*999)
          ENDIF
        CASE(part_deriv_s1_s2_s3)
          IF(SIZE(x,2)>=11) THEN
            SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
            CASE(2)
              z(1)=0.0_dp
              z(2)=0.0_dp
            CASE(3)  
              z(1)=-cos(x(2,1))*x(2,2)*x(2,4)*x(1,7)-&
                & sin(x(2,1))*(x(2,6)*x(1,7)+x(2,4)*x(1,9))-&
                & sin(x(2,1))*x(2,2)*x(1,10)+cos(x(2,1))*x(1,11)-&
                & cos(x(2,1))*x(2,2)*x(1,4)*x(2,7)-& 
                & sin(x(2,1))*(x(1,6)*x(2,7)+x(1,4)*x(2,9))+&
                & (-cos(x(2,1))*x(1,2)+sin(x(2,1))*x(1,1)*x(2,2))*&
                & x(2,4)*x(2,7)-x(1,1)*cos(x(2,1))*(x(2,6)*x(2,7)+&
                & x(2,4)*x(2,9))+(-sin(x(2,1))*x(1,2)-x(1,1)*& 
                & cos(x(2,1))*x(2,2))*x(2,10)-x(1,1)*&
                & sin(x(2,1))*x(2,11) !d3(x)/d(s1)d(s2)d(s3)
              z(2)=-sin(x(2,1))*x(2,2)*x(2,4)*x(1,7)+&
                & cos(x(2,1))*(x(2,6)*x(1,7)+x(2,4)*x(1,9))+&
                & cos(x(2,1))*x(2,2)*x(1,10)+sin(x(2,1))*x(1,11)-&
                & sin(x(2,1))*x(2,2)*x(1,4)*x(2,7)+&
                & cos(x(2,1))*(x(1,6)*x(2,7)+x(1,4)*x(2,9))+&
                & (-sin(x(2,1))*x(1,2)-x(1,1)*cos(x(2,1))*x(2,2))*&
                & x(2,4)*x(2,7)-x(1,1)*sin(x(2,1))*(x(2,6)*x(2,7)+&
                & x(2,4)*x(2,9))+(cos(x(2,1))*x(1,2)-x(1,1)*&
                & sin(x(2,1))*x(2,2))*x(2,10)+x(1,1)*&
                & cos(x(2,1))*x(2,11) !d3(y)/d(s1)d(s2)d(s3)
              z(3)=x(3,11) !d3(z)/d(s1)d(s2)d(s3)
            CASE DEFAULT
              CALL flagerror("Invalid number of coordinates",err,error,*999)
            END SELECT
          ELSE
            CALL flagerror("Not enough X derivatives supplied",err,error,*999)
          ENDIF
        CASE DEFAULT
          CALL flagerror("Invalid partial derivative type",err,error,*999)
        END SELECT
      CASE(coordinate_spherical_polar_type)
        IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
          SELECT CASE(part_deriv_type)
          CASE(no_part_deriv)
            z=coordinate_convert_to_rc(coordinate_system,x(:,1),err,error)
            IF(err/=0) GOTO 999
          CASE(part_deriv_s1,part_deriv_s1_s1,part_deriv_s2,part_deriv_s2_s2,&
            & part_deriv_s1_s2,part_deriv_s3,part_deriv_s3_s3,&
            & part_deriv_s1_s3,part_deriv_s2_s3,part_deriv_s1_s2_s3)
            CALL flagerror("Not implemented",err,error,*999)
          CASE DEFAULT
            CALL flagerror("Invalid partial derivative type",err,error,*999)
          END SELECT
        ELSE
          CALL flagerror("Invalid number of coordinates",err,error,*999)
        ENDIF
      CASE(coordinate_prolate_spheroidal_type)
        IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
          focus=coordinate_system%FOCUS
          SELECT CASE(part_deriv_type)
          CASE(no_part_deriv)
            z=coordinate_convert_to_rc(coordinate_system,x(:,1),err,error)
            IF(err/=0) GOTO 999
          CASE(part_deriv_s1)
            IF(SIZE(x,2)>=2) THEN
              z(1)=focus*sinh(x(1,1))*cos(x(2,1))*x(1,2)-&
                & focus*cosh(x(1,1))*sin(x(2,1))*x(2,2) !d(x)/d(s1)
              z(2)=focus*cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,2)+&
                & focus*sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,2)-&
                & focus*sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(3,2) !d(y)/d(s1)
              z(3)=focus*cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,2)+&
                & focus*sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,2)+&
                & focus*sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(3,2) !d(z)/d(s1)
            ELSE
              CALL flagerror("Invalid derivative type",err,error,*999)
            ENDIF
          CASE(part_deriv_s1_s1)
            CALL flagerror("Not implemented",err,error,*999)
          CASE(part_deriv_s2)
            IF(SIZE(x,2)>=4) THEN
              z(1)=focus*sinh(x(1,1))*cos(x(2,1))*x(1,4)-&
                & focus*cosh(x(1,1))*sin(x(2,1))*x(2,4) !d(x)/d(s2)
              z(2)=focus*cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,4)+&
                & focus*sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,4)-&
                & focus*sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(3,4) !d(y)/d(s2)
              z(3)=focus*cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,4)+&
                & focus*sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,4)+&
                & focus*sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(3,4) !d(z)/d(s2)
            ELSE
              CALL flagerror("Not enough X derivatives supplied",&
                & err,error,*999)
            ENDIF
          CASE(part_deriv_s2_s2)
            CALL flagerror("Not implemented",err,error,*999)
          CASE(part_deriv_s1_s2)
            IF(SIZE(x,2)>=6) THEN
              z(1)=focus*(sinh(x(1,1))*cos(x(2,1))*x(1,6)+&
                & x(1,2)*(cosh(x(1,1))*cos(x(2,1))*x(1,4)-&
                & sinh(x(1,1))*sin(x(2,1))*x(2,4))-&
                & cosh(x(1,1))*sin(x(2,1))*x(2,6)-&
                & x(2,2)*(sinh(x(1,1))*sin(x(2,1))*x(1,4)+&
                & cosh(x(1,1))*cos(x(2,1))*x(2,4))) !d2(x)/d(s1)d(s2)
              z(2)=focus*(cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,6)+&
                & x(1,2)*(sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(1,4)+cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*&
                & x(2,4)-cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(3,4))+sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*&
                & x(2,6)+x(2,2)*(cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*&
                & x(1,4)-sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(2,4)-&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(3,4))-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,6)-&
                & x(3,2)*(cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(1,4)+sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*&
                & x(2,4)+sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(3,4))) !d2(y)/d(s1)d(s2)
              z(3)=focus*(cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,6)+&
                & x(1,2)*(sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(1,4)+cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*&
                & x(2,4)+cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(3,4))+sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,6)+&
                & x(2,2)*(cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*&
                & x(1,4)-sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(2,4)+sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*&
                & x(3,4))+sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,6)+&
                & x(3,2)*(cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(1,4)+sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*&
                & x(2,4)-sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(3,4))) !d2(z)/d(s1)d(s2)
            ELSE
              CALL flagerror("Not enough X derivatives supplied",&
                & err,error,*999)
            ENDIF
          CASE(part_deriv_s3)
            IF(SIZE(x,2)>=7) THEN
              z(1)=focus*sinh(x(1,1))*cos(x(2,1))*x(1,7)-&
                & focus*cosh(x(1,1))*sin(x(2,1))*x(2,7) !d(x)/d(s3)
              z(2)=focus*cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,7)+&
                & focus*sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,7)-&
                & focus*sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(3,7) !d(y)/d(s3)
              z(3)=focus*cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,7)+&
                & focus*sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,7)+&
                & focus*sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(3,7) !d(z)/d(s3)
            ELSE
              CALL flagerror("Not enough X derivatives supplied",&
                & err,error,*999)
            ENDIF
          CASE(part_deriv_s3_s3)
            CALL flagerror("Not implemented",err,error,*999)
          CASE(part_deriv_s1_s3)
            IF(SIZE(x,2)>=9) THEN
              z(1)=focus*(sinh(x(1,1))*cos(x(2,1))*x(1,9)+&
                & x(1,2)*(cosh(x(1,1))*cos(x(2,1))*x(1,7)-&
                & sinh(x(1,1))*sin(x(2,1))*x(2,7))-&
                & cosh(x(1,1))*sin(x(2,1))*x(2,9)-&
                & x(2,2)*(sinh(x(1,1))*sin(x(2,1))*x(1,7)+&
                & cosh(x(1,1))*cos(x(2,1))*x(2,7))) !d2(x)/d(s1)d(s3)
              z(2)=focus*(cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,9)+&
                & x(1,2)*(sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,7)+&
                & cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,7)-&
                & cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,7))+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,9)+&
                & x(2,2)*(cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(1,7)-&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(2,7)-&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(3,7))-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,9)-&
                & x(3,2)*(cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,7)+&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))* x(2,7)+&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(3,7))) !d2(y)/d(s1)d(s3) 
              z(3)=focus*(cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,9)+&
                & x(1,2)*(sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,7)+&
                & cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,7)+&
                & cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,7))+&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,9)+&
                & x(2,2)*(cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(1,7)-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(2,7)+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(3,7))+&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,9)+&
                & x(3,2)*(cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,7)+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,7)-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(3,7))) !d2(z)/d(s1)d(s3)
            ELSE
              CALL flagerror("Not enough X derivatives supplied",&
                & err,error,*999)
            ENDIF
          CASE(part_deriv_s2_s3)
            IF(SIZE(x,2)>=10) THEN
              z(1)=focus*(sinh(x(1,1))*cos(x(2,1))*x(1,10)+&
                & x(1,4)*(cosh(x(1,1))*cos(x(2,1))*x(1,7)-&
                & sinh(x(1,1))*sin(x(2,1))*x(2,7))-&
                & cosh(x(1,1))*sin(x(2,1))*x(2,10)-&
                & x(2,4)*(sinh(x(1,1))*sin(x(2,1))*x(1,7)+&
                & cosh(x(1,1))*cos(x(2,1))*x(2,7))) !d2(x)/d(s2)d(s3)
              z(2)=focus*(cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,10)+&
                & x(1,4)*(sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,7)+&
                & cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,7)-&
                & cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,7))+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,10)+&
                & x(2,4)*(cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(1,7)-&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(2,7)-&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(3,7))-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,10)-&
                & x(3,4)*(cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,7)+&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,7)+&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(3,7))) !d2(y)/d(s2)d(s3)
              z(3)=focus*(cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,10)+&
                & x(1,4)*(sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,7)+&
                & cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,7)+&
                & cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,7))+&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,10)+&
                & x(2,4)*(cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(1,7)-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(2,7)+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(3,7))+&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,10)+&
                & x(3,4)*(cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,7)+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,7)-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(3,7))) !d2(z)/d(s2)d(s3)
            ELSE
              CALL flagerror("Not enough X derivatives supplied",&
                & err,error,*999)
            ENDIF
          CASE(part_deriv_s1_s2_s3)
            IF(SIZE(x,2)>=11) THEN
              z(1)=focus*((sinh(x(1,1))*cos(x(2,1))*x(1,2)-&
                & cosh(x(1,1))*sin(x(2,1))*x(2,2))*x(1,4)*x(1,7)+&
                & cosh(x(1,1))*cos(x(2,1))*(x(1,6)*x(1,7)+x(1,4)*x(1,9))+&
                & (-cosh(x(1,1))*sin(x(2,1))*x(1,2)-&
                & sinh(x(1,1))*cos(x(2,1))*x(2,2))*x(2,4)*x(1,7)-&
                & sinh(x(1,1))*sin(x(2,1))*(x(2,6)*x(1,7)+x(2,4)*x(1,9))+&
                & (cosh(x(1,1))*cos(x(2,1))*x(1,2)-&
                & sinh(x(1,1))*sin(x(2,1))*x(2,2))*x(1,10)+&
                & sinh(x(1,1))*cos(x(2,1))*x(1,11)+&
                & (-cosh(x(1,1))*sin(x(2,1))*x(1,2)-&
                & sinh(x(1,1))*cos(x(2,1))*x(2,2))*x(1,4)*x(2,7)-&
                & sinh(x(1,1))*sin(x(2,1))*(x(1,6)*x(2,7)+x(1,4)*x(2,9))+&
                & (-sinh(x(1,1))*cos(x(2,1))*x(1,2)+&
                & cosh(x(1,1))*sin(x(2,1))*x(2,2))*x(2,4)*x(2,7)-&
                & cosh(x(1,1))*cos(x(2,1))*(x(2,6)*x(2,7)+x(2,4)*x(2,9))+&
                & (-sinh(x(1,1))*sin(x(2,1))*x(1,2)-&
                & cosh(x(1,1))*cos(x(2,1))*x(2,2))*x(2,10)-&
                & cosh(x(1,1))*sin(x(2,1))*x(2,11)) !d3(x)/d(s1)d(s2)d(s3)
              z(2)=focus*((cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,2)+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,2))*&
                & x(1,4)*x(1,7)+sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & (x(1,6)*x(1,7)+x(1,4)*x(1,9))+&
                & (sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(1,2)-&
                & cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(2,2)-&
                & cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(3,2))*&
                & x(2,4)*x(1,7)+cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*&
                & (x(2,6)*x(1,7)+x(2,4)*x(1,9))+&
                & (-sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,2)-&
                & cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,2)-&
                & cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,2))*&
                & x(3,4)*x(1,7)-cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & (x(3,6)*x(1,7)+x(3,4)*x(1,9))+&
                & (sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,2)+&
                & cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,2)-&
                & cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,2))*x(1,10)+&
                & cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,11))+&
                & focus*((sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(1,2)-&
                & cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(2,2)-&
                & cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(3,2))*&
                & x(1,4)*x(2,7)+cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*&
                & (x(1,6)*x(2,7)+x(1,4)*x(2,9))+&
                & (-cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,2)-&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,2)+&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,2))*&
                & x(2,4)*x(2,7)-sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & (x(2,6)*x(2,7)+x(2,4)*x(2,9))+&
                & (-cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(1,2)+&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(3,2))*&
                & x(3,4)*x(2,7)-sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*&
                & (x(3,6)*x(2,7)+x(3,4)*x(2,9))+&
                & (cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(1,2)-&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(3,2))*x(2,10)+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,11))+&
                & focus*((-sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,2)-&
                & cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,2)-&
                & cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,2))*&
                & x(1,4)*x(3,7)-cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & (x(1,6)*x(3,7)+x(1,4)*x(3,9))+&
                & (-cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(1,2)+&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(3,2))*&
                & x(2,4)*x(3,7)-sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*&
                & (x(2,6)*x(3,7)+x(2,4)*x(3,9))+&
                & (-cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,2)-&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,2)+&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,2))*&
                & x(3,4)*x(3,7)-sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & (x(3,6)*x(3,7)+x(3,4)*x(3,9))+&
                & (-cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,2)-&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,2))*x(3,10)-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(3,11)) !d3(y)/d(s1)d(s2)d(s3)
              z(3)=focus*((cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,2)+&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,2)+&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,2))*&
                & x(1,4)*x(1,7)+sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & (x(1,6)*x(1,7)+x(1,4)*x(1,9))+&
                & (sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(1,2)-&
                & cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(2,2)+&
                & cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(3,2))*&
                & x(2,4)*x(1,7)+cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*&
                & (x(2,6)*x(1,7)+x(2,4)*x(1,9))+&
                & (sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,2)+&
                & cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,2)-&
                & cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,2))*&
                & x(3,4)*x(1,7)+cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & (x(3,6)*x(1,7)+x(3,4)*x(1,9))+&
                & (sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,2)+&
                & cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,2)+&
                & cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,2))*x(1,10)+&
                & cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,11))+&
                & focus*((sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(1,2)-&
                & cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(2,2)+&
                & cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(3,2))*&
                & x(1,4)*x(2,7)+cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*&
                & (x(1,6)*x(2,7)+x(1,4)*x(2,9))+&
                & (-cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,2)-&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,2))*&
                & x(2,4)*x(2,7)-sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & (x(2,6)*x(2,7)+x(2,4)*x(2,9))+&
                & (cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(1,2)-&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(3,2))*&
                & x(3,4)*x(2,7)+sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*&
                & (x(3,6)*x(2,7)+x(3,4)*x(2,9))+&
                & (cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(1,2)-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(2,2)+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(3,2))*x(2,10)+&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,11))+&
                & focus*((sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,2)+&
                & cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,2)-&
                & cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,2))*&
                & x(1,4)*x(3,7)+cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & (x(1,6)*x(3,7)+x(1,4)*x(3,9))+&
                & (cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(1,2)-&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(3,2))*&
                & x(2,4)*x(3,7)+sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*&
                & (x(2,6)*x(3,7)+x(2,4)*x(3,9))+&
                & (-cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,2)-&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,2))*&
                & x(3,4)*x(3,7)-sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & (x(3,6)*x(3,7)+x(3,4)*x(3,9))+&
                & (cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,2)+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,2))*x(3,10)+&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(3,11)) !d3(z)/d(s1)d(s2)d(s3)
            ELSE
              CALL flagerror("Not enough X derivatives supplied",&
                & err,error,*999)
            ENDIF
          CASE DEFAULT
            CALL flagerror("Invalid partial derivative type",err,error,*999)
          END SELECT
        ENDIF
      CASE(coordinate_oblate_spheroidal_type)
        IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
          focus=coordinate_system%FOCUS
          SELECT CASE(part_deriv_type)
          CASE(no_part_deriv)
            z=coordinate_convert_to_rc(coordinate_system,x(:,1),err,error)
            IF(err/=0) GOTO 999
          CASE(part_deriv_s1,part_deriv_s1_s1,part_deriv_s2,part_deriv_s2_s2,&
            & part_deriv_s1_s2,part_deriv_s3,part_deriv_s3_s3,&
            & part_deriv_s1_s3,part_deriv_s2_s3,part_deriv_s1_s2_s3)
            CALL flagerror("Not implemented",err,error,*999)
          CASE DEFAULT
            CALL flagerror("Invalid partial derivative type",err,error,*999)
          END SELECT
        ELSE
          CALL flagerror("Invalid number of coordinates",err,error,*999)
        ENDIF
      CASE DEFAULT
        CALL flagerror("Invalid coordinate type",err,error,*999)
      END SELECT
    ELSE
      CALL flagerror("The sizes of the vectors X and Z do not match",&
        & err,error,*999)
    ENDIF

    exits("COORDINATE_DERIVATIVE_CONVERT_TO_RC_DP")
    RETURN
999 errorsexits("COORDINATE_DERIVATIVE_CONVERT_TO_RC_DP",err,error)
    RETURN 1
  END SUBROUTINE coordinate_derivative_convert_to_rc_dp

  !
  !================================================================================================================================
  !
  
  SUBROUTINE coordinate_derivative_convert_to_rc_sp(COORDINATE_SYSTEM,PART_DERIV_TYPE,X,Z,&
    & err,error,*)
  
    !#### Subroutine: COORDINATE_DERIVATIVE_CONVERT_TO_RC_SP
    !###  Description:
    !###    COORDINATE_DERIVATIVE_CONVERT_TO_RC_SP performs a coordinate transformation from a
    !###    coordinate system identified by COORDINATE_SYSTEM at the point X
    !###    with coordinates/derivatives X(nj,nu) to the point with 
    !###    coordinates/derivatives Z(nj) in rectangular cartesian coordinates
    !###    for single precision coordinates.
    !###  Parent-function: COORDINATE_DERIVATIVE_CONVERT_TO_RC
    
    !Argument variables
    TYPE(coordinate_system_type), INTENT(IN) :: COORDINATE_SYSTEM
    INTEGER(INTG), INTENT(IN) :: PART_DERIV_TYPE
    REAL(SP), INTENT(IN) :: X(:,:)
    REAL(SP), INTENT(OUT) :: Z(:)
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local variables
    REAL(SP) :: FOCUS
    
    enters("COORDINATE_DERIVATIVE_CONVERT_TO_RC_SP",err,error,*999)
    
!!TODO: change all second index X(:,?) numbers to their apropriate constant
!!as defined in constants e.g. X(1,2) == X(1,PART_DERIV_S1)

    IF(SIZE(x,1)<coordinate_system%NUMBER_OF_DIMENSIONS) &
      & CALL flagerror("Size of X is less than the number of dimensions", &
      & err,error,*999)
    
    IF(SIZE(x,1)==SIZE(z,1)) THEN
      SELECT CASE(coordinate_system%TYPE)
      CASE(coordinate_rectangular_cartesian_type)
        IF(SIZE(x,2)>=part_deriv_type) THEN
          z=x(:,part_deriv_type)
        ELSE
          CALL flagerror("Invalid partial derivative type",err,error,*999)
        ENDIF
      CASE(coordinate_cylindrical_polar_type)
        SELECT CASE(part_deriv_type)
        CASE(no_part_deriv)
          z=coordinate_convert_to_rc(coordinate_system,x(:,1),err,error)
          IF(err/=0) GOTO 999
        CASE(part_deriv_s1)
          IF(SIZE(x,2)>=2) THEN
            SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
            CASE(2)
              z(1)=cos(x(2,1))*x(1,2)-x(1,1)*sin(x(2,1))*x(2,2) !d(x)/d(s1)
              z(2)=sin(x(2,1))*x(1,2)+x(1,1)*cos(x(2,1))*x(2,2) !d(y)/d(s1)
            CASE(3)
              z(1)=cos(x(2,1))*x(1,2)-x(1,1)*sin(x(2,1))*x(2,2) !d(x)/d(s1)
              z(2)=sin(x(2,1))*x(1,2)+x(1,1)*cos(x(2,1))*x(2,2) !d(y)/d(s1)
              z(3)=x(3,2) !d(z)/d(s1)
            CASE DEFAULT
              CALL flagerror("Invalid number of coordinates",err,error,*999)
            END SELECT
          ELSE
            CALL flagerror("Not enough X derivatives supplied",err,error,*999)
          ENDIF
        CASE(part_deriv_s1_s1)
          CALL flagerror("Not implemented",err,error,*999)
        CASE(part_deriv_s2)
          IF(SIZE(x,2)>=4) THEN
            SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
            CASE(2)
              z(1)=cos(x(2,1))*x(1,4)-x(1,1)*sin(x(2,1))*x(2,4) !d(x)/d(s2)
              z(2)=sin(x(2,1))*x(1,4)+x(1,1)*cos(x(2,1))*x(2,4) !d(y)/d(s2)
            CASE(3)
              z(1)=cos(x(2,1))*x(1,4)-x(1,1)*sin(x(2,1))*x(2,4) !d(x)/d(s2)
              z(2)=sin(x(2,1))*x(1,4)+x(1,1)*cos(x(2,1))*x(2,4) !d(y)/d(s2)
              z(3)=x(3,4) !d(z)/d(s2)
            CASE DEFAULT
              CALL flagerror("Invalid number of coordinates",err,error,*999)
            END SELECT
          ELSE
            CALL flagerror("Not enough X derivatives supplied",err,error,*999)
          ENDIF
        CASE(part_deriv_s2_s2)
          CALL flagerror("Not implemented",err,error,*999)
        CASE(part_deriv_s1_s2)
          IF(SIZE(x,2)>=6) THEN
            SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
            CASE(2)
              z(1)=cos(x(2,1))*x(1,6)-x(1,2)*sin(x(2,1))*x(2,4)-&
                & (x(1,4)*sin(x(2,1))*x(2,2)+x(1,1)*cos(x(2,1))*&
                & x(2,2)*x(2,4)+x(1,1)*sin(x(2,1))*x(2,6)) !d2(x)/d(s1)d(s2)
              z(2)=sin(x(2,1))*x(1,6)+x(1,2)*cos(x(2,1))*x(2,4)+&
                & (x(1,4)*cos(x(2,1))*x(2,2)-x(1,1)*sin(x(2,1))*&
                & x(2,2)*x(2,4)+x(1,1)*cos(x(2,1))*x(2,6)) !d2(y)/d(s1)d(s2)
            CASE(3)
              z(1)=cos(x(2,1))*x(1,6)-x(1,2)*sin(x(2,1))*x(2,4)-&
                & (x(1,4)*sin(x(2,1))*x(2,2)+x(1,1)*cos(x(2,1))*&
                & x(2,2)*x(2,4)+x(1,1)*sin(x(2,1))*x(2,6)) !d2(x)/d(s1)d(s2)
              z(2)=sin(x(2,1))*x(1,6)+x(1,2)*cos(x(2,1))*x(2,4)+&
                & (x(1,4)*cos(x(2,1))*x(2,2)-x(1,1)*sin(x(2,1))*&
                & x(2,2)*x(2,4)+x(1,1)*cos(x(2,1))*x(2,6)) !d2(y)/d(s1)d(s2)
              z(3)=x(3,6) !d2(z)/d(s1)d(s2)
            CASE DEFAULT
              CALL flagerror("Invalid number of coordinates",err,error,*999)
            END SELECT
          ELSE
            CALL flagerror("Not enough X derivatives supplied",err,error,*999)
          ENDIF
        CASE(part_deriv_s3)
          IF(SIZE(x,2)>=7) THEN
            SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
            CASE(2)
              z(1)=0.0_sp
              z(2)=0.0_sp
            CASE(3)
              z(1)=cos(x(2,1))*x(1,7)-x(1,1)*sin(x(2,1))*x(2,7) !d(x)/d(s3)
              z(2)=sin(x(2,1))*x(1,7)+x(1,1)*cos(x(2,1))*x(2,7) !d(y)/d(s3)
              z(3)=x(3,7) !d(z)/d(s3)
            CASE DEFAULT
              CALL flagerror("Invalid number of coordinates",err,error,*999)
            END SELECT
          ELSE
            CALL flagerror("Not enough X derivatives supplied",err,error,*999)
          ENDIF
        CASE(part_deriv_s3_s3)
          CALL flagerror("Not implemented",err,error,*999)
        CASE(part_deriv_s1_s3)
          IF(SIZE(x,2)>=9) THEN
            SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
            CASE(2)
              z(1)=0.0_sp
              z(2)=0.0_sp
            CASE(3)
              z(1)=cos(x(2,1))*x(1,9)-x(1,2)*sin(x(2,1))*x(2,7)-&
                & (x(1,7)*sin(x(2,1))*x(2,2)+x(1,1)*cos(x(2,1))*&
                & x(2,2)*x(2,7)+x(1,1)*sin(x(2,1))*x(2,9)) !d2(x)/d(s1)d(s3)
              z(2)=sin(x(2,1))*x(1,9)+x(1,2)*cos(x(2,1))*x(2,7)+&
                & (x(1,7)*cos(x(2,1))*x(2,2)-x(1,1)*sin(x(2,1))*&
                & x(2,2)*x(2,7)+x(1,1)*cos(x(2,1))*x(2,9)) !d2(y)/d(s1)d(s3)
              z(3)=x(3,9) !d2(z)/d(s1)d(s3)
            CASE DEFAULT
              CALL flagerror("Invalid number of coordinates",err,error,*999)
            END SELECT
          ELSE
            CALL flagerror("Not enough X derivatives supplied",err,error,*999)
          ENDIF
        CASE(part_deriv_s2_s3)
          IF(SIZE(x,2)>=10) THEN
            SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
            CASE(2)
              z(1)=0.0_sp
              z(2)=0.0_sp
            CASE(3)
              z(1)=cos(x(2,1))*x(1,10)-x(1,4)*sin(x(2,1))*x(2,7)-&
                & (x(1,7)*sin(x(2,1))*x(2,4)+x(1,1)*cos(x(2,1))*&
                & x(2,4)*x(2,7)+x(1,1)*sin(x(2,1))*x(2,10)) !d2(x)/d(s2)d(s3)
              z(2)=sin(x(2,1))*x(1,10)+x(1,4)*cos(x(2,1))*x(2,7)+&
                & (x(1,7)*cos(x(2,1))*x(2,4)-x(1,1)*sin(x(2,1))*&
                & x(2,4)*x(2,7)+x(1,1)*cos(x(2,1))*x(2,10)) !d2(y)/d(s2)d(s3)
              z(3)=x(3,10) !d2(z)/d(s2)d(s3)
            CASE DEFAULT
              CALL flagerror("Invalid number of coordinates",err,error,*999)
            END SELECT
          ELSE
            CALL flagerror("Not enough X derivatives supplied",err,error,*999)
          ENDIF
        CASE(part_deriv_s1_s2_s3)
          IF(SIZE(x,2)>=11) THEN
            SELECT CASE(coordinate_system%NUMBER_OF_DIMENSIONS)
            CASE(2)
              z(1)=0.0_sp
              z(2)=0.0_sp
            CASE(3)  
              z(1)=-cos(x(2,1))*x(2,2)*x(2,4)*x(1,7)-&
                & sin(x(2,1))*(x(2,6)*x(1,7)+x(2,4)*x(1,9))-&
                & sin(x(2,1))*x(2,2)*x(1,10)+cos(x(2,1))*x(1,11)-&
                & cos(x(2,1))*x(2,2)*x(1,4)*x(2,7)-& 
                & sin(x(2,1))*(x(1,6)*x(2,7)+x(1,4)*x(2,9))+&
                & (-cos(x(2,1))*x(1,2)+sin(x(2,1))*x(1,1)*x(2,2))*&
                & x(2,4)*x(2,7)-x(1,1)*cos(x(2,1))*(x(2,6)*x(2,7)+&
                & x(2,4)*x(2,9))+(-sin(x(2,1))*x(1,2)-x(1,1)*& 
                & cos(x(2,1))*x(2,2))*x(2,10)-x(1,1)*&
                & sin(x(2,1))*x(2,11) !d3(x)/d(s1)d(s2)d(s3)
              z(2)=-sin(x(2,1))*x(2,2)*x(2,4)*x(1,7)+&
                & cos(x(2,1))*(x(2,6)*x(1,7)+x(2,4)*x(1,9))+&
                & cos(x(2,1))*x(2,2)*x(1,10)+sin(x(2,1))*x(1,11)-&
                & sin(x(2,1))*x(2,2)*x(1,4)*x(2,7)+&
                & cos(x(2,1))*(x(1,6)*x(2,7)+x(1,4)*x(2,9))+&
                & (-sin(x(2,1))*x(1,2)-x(1,1)*cos(x(2,1))*x(2,2))*&
                & x(2,4)*x(2,7)-x(1,1)*sin(x(2,1))*(x(2,6)*x(2,7)+&
                & x(2,4)*x(2,9))+(cos(x(2,1))*x(1,2)-x(1,1)*&
                & sin(x(2,1))*x(2,2))*x(2,10)+x(1,1)*&
                & cos(x(2,1))*x(2,11) !d3(y)/d(s1)d(s2)d(s3)
              z(3)=x(3,11) !d3(z)/d(s1)d(s2)d(s3)
            CASE DEFAULT
              CALL flagerror("Invalid number of coordinates",err,error,*999)
            END SELECT
          ELSE
            CALL flagerror("Not enough X derivatives supplied",err,error,*999)
          ENDIF
        CASE DEFAULT
          CALL flagerror("Invalid partial derivative type",err,error,*999)
        END SELECT
      CASE(coordinate_spherical_polar_type)
        IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
          SELECT CASE(part_deriv_type)
          CASE(no_part_deriv)
            z=coordinate_convert_to_rc(coordinate_system,x(:,1),err,error)
            IF(err/=0) GOTO 999
          CASE(part_deriv_s1,part_deriv_s1_s1,part_deriv_s2,part_deriv_s2_s2,&
            & part_deriv_s1_s2,part_deriv_s3,part_deriv_s3_s3,&
            & part_deriv_s1_s3,part_deriv_s2_s3,part_deriv_s1_s2_s3)
            CALL flagerror("Not implemented",err,error,*999)
          CASE DEFAULT
            CALL flagerror("Invalid partial derivative type",err,error,*999)
          END SELECT
        ELSE
          CALL flagerror("Invalid number of coordinates",err,error,*999)
        ENDIF
      CASE(coordinate_prolate_spheroidal_type)
        IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
          focus=REAL(coordinate_system%focus,sp)
          SELECT CASE(part_deriv_type)
          CASE(no_part_deriv)
            z=coordinate_convert_to_rc(coordinate_system,x(:,1),err,error)
            IF(err/=0) GOTO 999
          CASE(part_deriv_s1)
            IF(SIZE(x,2)>=2) THEN
              z(1)=focus*sinh(x(1,1))*cos(x(2,1))*x(1,2)-&
                & focus*cosh(x(1,1))*sin(x(2,1))*x(2,2) !d(x)/d(s1)
              z(2)=focus*cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,2)+&
                & focus*sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,2)-&
                & focus*sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(3,2) !d(y)/d(s1)
              z(3)=focus*cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,2)+&
                & focus*sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,2)+&
                & focus*sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(3,2) !d(z)/d(s1)
            ELSE
              CALL flagerror("Not enough X derivatives supplied", &
                & err,error,*999)
            ENDIF
          CASE(part_deriv_s1_s1)
            CALL flagerror("Not implemented",err,error,*999)
          CASE(part_deriv_s2)
            IF(SIZE(x,2)>=4) THEN
              z(1)=focus*sinh(x(1,1))*cos(x(2,1))*x(1,4)-&
                & focus*cosh(x(1,1))*sin(x(2,1))*x(2,4) !d(x)/d(s2)
              z(2)=focus*cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,4)+&
                & focus*sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,4)-&
                & focus*sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(3,4) !d(y)/d(s2)
              z(3)=focus*cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,4)+&
                & focus*sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,4)+&
                & focus*sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(3,4) !d(z)/d(s2)
            ELSE
              CALL flagerror("Not enough X derivatives supplied",&
                & err,error,*999)
            ENDIF
          CASE(part_deriv_s2_s2)
            CALL flagerror("Not implemented",err,error,*999)
          CASE(part_deriv_s1_s2)
            IF(SIZE(x,2)>=6) THEN
              z(1)=focus*(sinh(x(1,1))*cos(x(2,1))*x(1,6)+&
                & x(1,2)*(cosh(x(1,1))*cos(x(2,1))*x(1,4)-&
                & sinh(x(1,1))*sin(x(2,1))*x(2,4))-&
                & cosh(x(1,1))*sin(x(2,1))*x(2,6)-&
                & x(2,2)*(sinh(x(1,1))*sin(x(2,1))*x(1,4)+&
                & cosh(x(1,1))*cos(x(2,1))*x(2,4))) !d2(x)/d(s1)d(s2)
              z(2)=focus*(cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,6)+&
                & x(1,2)*(sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(1,4)+cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*&
                & x(2,4)-cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(3,4))+sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*&
                & x(2,6)+x(2,2)*(cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*&
                & x(1,4)-sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(2,4)-&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(3,4))-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,6)-&
                & x(3,2)*(cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(1,4)+sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*&
                & x(2,4)+sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(3,4))) !d2(y)/d(s1)d(s2)
              z(3)=focus*(cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,6)+&
                & x(1,2)*(sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(1,4)+cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*&
                & x(2,4)+cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(3,4))+sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,6)+&
                & x(2,2)*(cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*&
                & x(1,4)-sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(2,4)+sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*&
                & x(3,4))+sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,6)+&
                & x(3,2)*(cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(1,4)+sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*&
                & x(2,4)-sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(3,4))) !d2(z)/d(s1)d(s2)
            ELSE
              CALL flagerror("Not enough X derivatives supplied",&
                & err,error,*999)
            ENDIF
          CASE(part_deriv_s3)
            IF(SIZE(x,2)>=7) THEN
              z(1)=focus*sinh(x(1,1))*cos(x(2,1))*x(1,7)-&
                & focus*cosh(x(1,1))*sin(x(2,1))*x(2,7) !d(x)/d(s3)
              z(2)=focus*cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,7)+&
                & focus*sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,7)-&
                & focus*sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(3,7) !d(y)/d(s3)
              z(3)=focus*cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,7)+&
                & focus*sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,7)+&
                & focus*sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(3,7) !d(z)/d(s3)
            ELSE
              CALL flagerror("Not enough X derivatives supplied",&
                & err,error,*999)
            ENDIF
          CASE(part_deriv_s3_s3)
            CALL flagerror("Not implemented",err,error,*999)
          CASE(part_deriv_s1_s3)
            IF(SIZE(x,2)>=9) THEN
              z(1)=focus*(sinh(x(1,1))*cos(x(2,1))*x(1,9)+&
                & x(1,2)*(cosh(x(1,1))*cos(x(2,1))*x(1,7)-&
                & sinh(x(1,1))*sin(x(2,1))*x(2,7))-&
                & cosh(x(1,1))*sin(x(2,1))*x(2,9)-&
                & x(2,2)*(sinh(x(1,1))*sin(x(2,1))*x(1,7)+&
                & cosh(x(1,1))*cos(x(2,1))*x(2,7))) !d2(x)/d(s1)d(s3)
              z(2)=focus*(cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,9)+&
                & x(1,2)*(sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,7)+&
                & cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,7)-&
                & cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,7))+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,9)+&
                & x(2,2)*(cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(1,7)-&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(2,7)-&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(3,7))-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,9)-&
                & x(3,2)*(cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,7)+&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))* x(2,7)+&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(3,7))) !d2(y)/d(s1)d(s3) 
              z(3)=focus*(cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,9)+&
                & x(1,2)*(sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,7)+&
                & cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,7)+&
                & cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,7))+&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,9)+&
                & x(2,2)*(cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(1,7)-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(2,7)+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(3,7))+&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,9)+&
                & x(3,2)*(cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,7)+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,7)-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(3,7))) !d2(z)/d(s1)d(s3)
            ELSE
              CALL flagerror("Not enough X derivatives supplied",&
                & err,error,*999)
            ENDIF
          CASE(part_deriv_s2_s3)
            IF(SIZE(x,2)>=10) THEN
              z(1)=focus*(sinh(x(1,1))*cos(x(2,1))*x(1,10)+&
                & x(1,4)*(cosh(x(1,1))*cos(x(2,1))*x(1,7)-&
                & sinh(x(1,1))*sin(x(2,1))*x(2,7))-&
                & cosh(x(1,1))*sin(x(2,1))*x(2,10)-&
                & x(2,4)*(sinh(x(1,1))*sin(x(2,1))*x(1,7)+&
                & cosh(x(1,1))*cos(x(2,1))*x(2,7))) !d2(x)/d(s2)d(s3)
              z(2)=focus*(cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,10)+&
                & x(1,4)*(sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,7)+&
                & cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,7)-&
                & cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,7))+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,10)+&
                & x(2,4)*(cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(1,7)-&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(2,7)-&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(3,7))-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,10)-&
                & x(3,4)*(cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,7)+&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,7)+&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(3,7))) !d2(y)/d(s2)d(s3)
              z(3)=focus*(cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,10)+&
                & x(1,4)*(sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,7)+&
                & cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,7)+&
                & cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,7))+&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,10)+&
                & x(2,4)*(cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(1,7)-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(2,7)+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(3,7))+&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,10)+&
                & x(3,4)*(cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,7)+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,7)-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(3,7))) !d2(z)/d(s2)d(s3)
            ELSE
              CALL flagerror("Not enough X derivatives supplied",&
                & err,error,*999)
            ENDIF
          CASE(part_deriv_s1_s2_s3)
            IF(SIZE(x,2)>=11) THEN
              z(1)=focus*((sinh(x(1,1))*cos(x(2,1))*x(1,2)-&
                & cosh(x(1,1))*sin(x(2,1))*x(2,2))*x(1,4)*x(1,7)+&
                & cosh(x(1,1))*cos(x(2,1))*(x(1,6)*x(1,7)+x(1,4)*x(1,9))+&
                & (-cosh(x(1,1))*sin(x(2,1))*x(1,2)-&
                & sinh(x(1,1))*cos(x(2,1))*x(2,2))*x(2,4)*x(1,7)-&
                & sinh(x(1,1))*sin(x(2,1))*(x(2,6)*x(1,7)+x(2,4)*x(1,9))+&
                & (cosh(x(1,1))*cos(x(2,1))*x(1,2)-&
                & sinh(x(1,1))*sin(x(2,1))*x(2,2))*x(1,10)+&
                & sinh(x(1,1))*cos(x(2,1))*x(1,11)+&
                & (-cosh(x(1,1))*sin(x(2,1))*x(1,2)-&
                & sinh(x(1,1))*cos(x(2,1))*x(2,2))*x(1,4)*x(2,7)-&
                & sinh(x(1,1))*sin(x(2,1))*(x(1,6)*x(2,7)+x(1,4)*x(2,9))+&
                & (-sinh(x(1,1))*cos(x(2,1))*x(1,2)+&
                & cosh(x(1,1))*sin(x(2,1))*x(2,2))*x(2,4)*x(2,7)-&
                & cosh(x(1,1))*cos(x(2,1))*(x(2,6)*x(2,7)+x(2,4)*x(2,9))+&
                & (-sinh(x(1,1))*sin(x(2,1))*x(1,2)-&
                & cosh(x(1,1))*cos(x(2,1))*x(2,2))*x(2,10)-&
                & cosh(x(1,1))*sin(x(2,1))*x(2,11)) !d3(x)/d(s1)d(s2)d(s3)
              z(2)=focus*((cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,2)+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,2))*&
                & x(1,4)*x(1,7)+sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & (x(1,6)*x(1,7)+x(1,4)*x(1,9))+&
                & (sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(1,2)-&
                & cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(2,2)-&
                & cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(3,2))*&
                & x(2,4)*x(1,7)+cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*&
                & (x(2,6)*x(1,7)+x(2,4)*x(1,9))+&
                & (-sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,2)-&
                & cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,2)-&
                & cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,2))*&
                & x(3,4)*x(1,7)-cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & (x(3,6)*x(1,7)+x(3,4)*x(1,9))+&
                & (sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,2)+&
                & cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,2)-&
                & cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,2))*x(1,10)+&
                & cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,11))+&
                & focus*((sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(1,2)-&
                & cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(2,2)-&
                & cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(3,2))*&
                & x(1,4)*x(2,7)+cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*&
                & (x(1,6)*x(2,7)+x(1,4)*x(2,9))+&
                & (-cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,2)-&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,2)+&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,2))*&
                & x(2,4)*x(2,7)-sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & (x(2,6)*x(2,7)+x(2,4)*x(2,9))+&
                & (-cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(1,2)+&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(3,2))*&
                & x(3,4)*x(2,7)-sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*&
                & (x(3,6)*x(2,7)+x(3,4)*x(2,9))+&
                & (cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(1,2)-&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(3,2))*x(2,10)+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,11))+&
                & focus*((-sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,2)-&
                & cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,2)-&
                & cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,2))*&
                & x(1,4)*x(3,7)-cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & (x(1,6)*x(3,7)+x(1,4)*x(3,9))+&
                & (-cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(1,2)+&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(3,2))*&
                & x(2,4)*x(3,7)-sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*&
                & (x(2,6)*x(3,7)+x(2,4)*x(3,9))+&
                & (-cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,2)-&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,2)+&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,2))*&
                & x(3,4)*x(3,7)-sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & (x(3,6)*x(3,7)+x(3,4)*x(3,9))+&
                & (-cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,2)-&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,2))*x(3,10)-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & x(3,11)) !d3(y)/d(s1)d(s2)d(s3)
              z(3)=focus*((cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,2)+&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,2)+&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,2))*&
                & x(1,4)*x(1,7)+sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & (x(1,6)*x(1,7)+x(1,4)*x(1,9))+&
                & (sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(1,2)-&
                & cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(2,2)+&
                & cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(3,2))*&
                & x(2,4)*x(1,7)+cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*&
                & (x(2,6)*x(1,7)+x(2,4)*x(1,9))+&
                & (sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,2)+&
                & cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,2)-&
                & cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,2))*&
                & x(3,4)*x(1,7)+cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & (x(3,6)*x(1,7)+x(3,4)*x(1,9))+&
                & (sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,2)+&
                & cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,2)+&
                & cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,2))*x(1,10)+&
                & cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,11))+&
                & focus*((sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(1,2)-&
                & cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(2,2)+&
                & cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(3,2))*&
                & x(1,4)*x(2,7)+cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*&
                & (x(1,6)*x(2,7)+x(1,4)*x(2,9))+&
                & (-cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,2)-&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,2))*&
                & x(2,4)*x(2,7)-sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & (x(2,6)*x(2,7)+x(2,4)*x(2,9))+&
                & (cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(1,2)-&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(3,2))*&
                & x(3,4)*x(2,7)+sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*&
                & (x(3,6)*x(2,7)+x(3,4)*x(2,9))+&
                & (cosh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(1,2)-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(2,2)+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(3,2))*x(2,10)+&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,11))+&
                & focus*((sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,2)+&
                & cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,2)-&
                & cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,2))*&
                & x(1,4)*x(3,7)+cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & (x(1,6)*x(3,7)+x(1,4)*x(3,9))+&
                & (cosh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(1,2)-&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(3,2))*&
                & x(2,4)*x(3,7)+sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*&
                & (x(2,6)*x(3,7)+x(2,4)*x(3,9))+&
                & (-cosh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(1,2)-&
                & sinh(x(1,1))*cos(x(2,1))*sin(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(3,2))*&
                & x(3,4)*x(3,7)-sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*&
                & (x(3,6)*x(3,7)+x(3,4)*x(3,9))+&
                & (cosh(x(1,1))*sin(x(2,1))*cos(x(3,1))*x(1,2)+&
                & sinh(x(1,1))*cos(x(2,1))*cos(x(3,1))*x(2,2)-&
                & sinh(x(1,1))*sin(x(2,1))*sin(x(3,1))*x(3,2))*x(3,10)+&
                & sinh(x(1,1))*sin(x(2,1))*cos(x(3,1))*&
                & x(3,11)) !d3(z)/d(s1)d(s2)d(s3)
            ELSE
              CALL flagerror("Not enough X derivatives supplied",&
                & err,error,*999)
            ENDIF
          CASE DEFAULT
            CALL flagerror("Invalid partial derivative type",err,error,*999)
          END SELECT
        ENDIF
      CASE(coordinate_oblate_spheroidal_type)
        IF(coordinate_system%NUMBER_OF_DIMENSIONS==3) THEN
          SELECT CASE(part_deriv_type)
          CASE(no_part_deriv)
            z=coordinate_convert_to_rc(coordinate_system,x(:,1),err,error)
            IF(err/=0) GOTO 999
          CASE(part_deriv_s1,part_deriv_s1_s1,part_deriv_s2,part_deriv_s2_s2,&
            & part_deriv_s1_s2,part_deriv_s3,part_deriv_s3_s3,&
            & part_deriv_s1_s3,part_deriv_s2_s3,part_deriv_s1_s2_s3)
            CALL flagerror("Not implemented",err,error,*999)
          CASE DEFAULT
            CALL flagerror("Invalid partial derivative type",err,error,*999)
          END SELECT
        ELSE
          CALL flagerror("Invalid number of coordinates",err,error,*999)
        ENDIF
      CASE DEFAULT
        CALL flagerror("Invalid coordinate type",err,error,*999)
      END SELECT
    ELSE
      CALL flagerror("The sizes of the vectors X and Z do not match",&
        & err,error,*999)
    ENDIF

    exits("COORDINATE_DERIVATIVE_CONVERT_TO_RC_SP")
    RETURN
999 errorsexits("COORDINATE_DERIVATIVE_CONVERT_TO_RC_SP",err,error)
    RETURN 1
  END SUBROUTINE coordinate_derivative_convert_to_rc_sp

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_derivative_norm(COORDINATE_SYSTEM,PART_DERIV_INDEX,INTERPOLATED_POINT,DERIV_NORM,ERR,ERROR,*)
  
    !Argument variables
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    INTEGER(INTG), INTENT(IN) :: PART_DERIV_INDEX
    TYPE(field_interpolated_point_type), POINTER :: INTERPOLATED_POINT
    REAL(DP), INTENT(OUT) :: DERIV_NORM
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local variables
    INTEGER(INTG) :: component_idx,NUMBER_OF_COMPONENTS
    REAL(DP) :: FOCUS,SL,SM
    TYPE(varying_string) :: LOCAL_ERROR
    
    enters("COORDINATE_DERIVATIVE_NORM",err,error,*999)

    deriv_norm=0.0_dp
    IF(ASSOCIATED(coordinate_system)) THEN
      IF(ASSOCIATED(interpolated_point)) THEN
        IF(interpolated_point%PARTIAL_DERIVATIVE_TYPE>=first_part_deriv) THEN
          IF(part_deriv_index<=interpolated_point%MAX_PARTIAL_DERIVATIVE_INDEX) THEN
            number_of_components=SIZE(interpolated_point%VALUES,1)
            SELECT CASE(part_deriv_index)
            CASE(part_deriv_s1,part_deriv_s2,part_deriv_s3)
              SELECT CASE(coordinate_system%TYPE)
              CASE(coordinate_rectangular_cartesian_type)
                DO component_idx=1,number_of_components
                  deriv_norm=deriv_norm+interpolated_point%VALUES(component_idx,part_deriv_index)**2
                ENDDO !component_index
              CASE(coordinate_cylindrical_polar_type)
                IF(number_of_components==2) THEN
                  deriv_norm=interpolated_point%VALUES(1,part_deriv_index)**2+(interpolated_point%VALUES(1,1)* &
                    & interpolated_point%VALUES(2,part_deriv_index))**2
                ELSE IF(number_of_components==3) THEN
                  deriv_norm=interpolated_point%VALUES(1,part_deriv_index)**2+(interpolated_point%VALUES(1,1)* &
                    & interpolated_point%VALUES(2,part_deriv_index))**2+interpolated_point%VALUES(3,part_deriv_index)**2
                ELSE
                  local_error="The number of components for the interpolated point of "// &
                    & trim(number_to_vstring(number_of_components,"*",err,error))// &
                    & " is invalid for a cylindrical polar coordinate system."
                  CALL flagerror(local_error,err,error,*999)
                ENDIF
              CASE(coordinate_spherical_polar_type)
                deriv_norm=interpolated_point%VALUES(1,part_deriv_index)**2+(interpolated_point%VALUES(1,1)* &
                  & interpolated_point%VALUES(2,part_deriv_index)*cos(interpolated_point%VALUES(3,1)))**2+ &
                  & (interpolated_point%VALUES(1,1)*interpolated_point%VALUES(3,part_deriv_index))**2
              CASE(coordinate_prolate_spheroidal_type)
                focus=coordinate_system%FOCUS
                sl=sinh(interpolated_point%VALUES(1,1))
                sm=sin(interpolated_point%VALUES(2,1))
                deriv_norm=focus*focus*((sl*sl+sm*sm)*(interpolated_point%VALUES(1,part_deriv_index)**2+ &
                  & interpolated_point%VALUES(2,part_deriv_index))**2)+(sl*sm*interpolated_point%VALUES(3,part_deriv_index))**2
              CASE(coordinate_oblate_spheroidal_type)
                CALL flagerror("Not implemented.",err,error,*999)
              CASE DEFAULT
                local_error="The coordinate system type of "//trim(number_to_vstring(coordinate_system%TYPE,"*",err,error))// &
                  & " is invalid."
                CALL flagerror(local_error,err,error,*999)
              END SELECT
              deriv_norm=sqrt(deriv_norm)
            CASE DEFAULT
              local_error="The partial derivative index of "//trim(number_to_vstring(part_deriv_index,"*",err,error))// &
                & " is invalid."
              CALL flagerror(local_error,err,error,*999)
            END SELECT
          ELSE
            local_error="The partial derivative index of "//trim(number_to_vstring(part_deriv_index,"*",err,error))// &
              & " is invalid. The interpolated point has a maximum number of partial derivatives of "// &
              & trim(number_to_vstring(interpolated_point%MAX_PARTIAL_DERIVATIVE_INDEX,"*",err,error))//"."
            CALL flagerror(local_error,err,error,*999)
          ENDIF
        ELSE
          CALL flagerror("The point has not been interpolated to include first derivative values.",err,error,*999)
        ENDIF          
      ELSE
        CALL flagerror("Interpolated point is not associated.",err,error,*999)
      ENDIF
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF
    
    exits("COORDINATE_DERIVATIVE_NORM")
    RETURN
999 errorsexits("COORDINATE_DERIVATIVE_NORM",err,error)
    RETURN 1
  END SUBROUTINE coordinate_derivative_norm

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_interpolation_adjust(COORDINATE_SYSTEM,PARTIAL_DERIVATIVE_INDEX,VALUE,ERR,ERROR,*)
  
    !Argument variables
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    INTEGER(INTG), INTENT(IN) :: PARTIAL_DERIVATIVE_INDEX
    REAL(DP), INTENT(INOUT) :: VALUE
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local variables
    REAL(DP) :: COSHX,CSS,D,DES,FOCUS,R,SS,SINHX,THETA
    TYPE(varying_string) :: LOCAL_ERROR
    
    enters("COORDINATE_INTERPOLATION_ADJUST",err,error,*999)

    IF(ASSOCIATED(coordinate_system)) THEN
      SELECT CASE(coordinate_system%TYPE)
      CASE(coordinate_rectangular_cartesian_type)
        !Do nothing
      CASE(coordinate_cylindrical_polar_type)
        SELECT CASE(coordinate_system%RADIAL_INTERPOLATION_TYPE)
        CASE(coordinate_radial_interpolation_type)
          !Do nothing
        CASE(coordinate_radial_squared_interpolation_type)
          r=sqrt(VALUE)
          IF(partial_derivative_index==no_part_deriv) THEN
            VALUE=r
          ELSE
            VALUE=VALUE/(2.0_dp*r)
          ENDIF
        CASE DEFAULT
          local_error="The radial interpolation type of "//trim(number_to_vstring(coordinate_system% &
            & radial_interpolation_type,"*",err,error))//" is invalid for a cylindrical coordinate system."
          CALL flagerror(local_error,err,error,*999)
        END SELECT
      CASE(coordinate_spherical_polar_type)
        SELECT CASE(coordinate_system%RADIAL_INTERPOLATION_TYPE)
        CASE(coordinate_radial_interpolation_type)
          !Do nothing
        CASE(coordinate_radial_squared_interpolation_type)
          r=VALUE**(1.0_dp/3.0_dp)
          IF(partial_derivative_index==no_part_deriv) THEN
            VALUE=r
          ELSE
            VALUE=VALUE/(3.0_dp*r*r)
          ENDIF
        CASE DEFAULT
          local_error="The radial interpolation type of "//trim(number_to_vstring(coordinate_system% &
            & radial_interpolation_type,"*",err,error))//" is invalid for a cylindrical/spherical coordinate system."
          CALL flagerror(local_error,err,error,*999)
        END SELECT
      CASE(coordinate_prolate_spheroidal_type)
        SELECT CASE(coordinate_system%RADIAL_INTERPOLATION_TYPE)
        CASE(coordinate_radial_interpolation_type)
          !Do nothing
        CASE(coordinate_radial_squared_interpolation_type)
          focus=coordinate_system%FOCUS
          ss=VALUE/(focus*focus)
          sinhx=sqrt(ss)
          coshx=sqrt(1.0_dp+ss)
          IF(partial_derivative_index==no_part_deriv) THEN
            VALUE=log(sinhx+coshx)
          ELSE
            VALUE=VALUE/(2.0_dp*focus*focus*sinhx*coshx)
          ENDIF
        CASE(coordinate_radial_cubed_interpolation_type)
          focus=coordinate_system%FOCUS
          css=VALUE/(focus**3.0_dp)
          des=css*css-4.0_dp/27.0_dp
          IF(des>0.0_dp) THEN
            d=((css+sqrt(des))/2.0_dp)**(1.0_dp/3.0_dp)
            coshx=d+1.0_dp/(3.0_dp*d)
          ELSE
            theta=acos(css*sqrt(27.0_dp)/2.0_dp)
            coshx=2.0_dp/sqrt(3.0_dp)*cos(theta/3.0_dp)
          ENDIF
          sinhx=sqrt(abs(coshx*coshx-1.0_dp))
          IF(partial_derivative_index==no_part_deriv) THEN
            VALUE=log(sinhx+coshx)
          ELSE
            VALUE=VALUE/((3.0_dp*coshx*coshx-1.0_dp)*sinhx)/(focus**3.0_dp)
          ENDIF
        CASE DEFAULT
          local_error="The radial interpolation type of "//trim(number_to_vstring(coordinate_system% &
            & radial_interpolation_type,"*",err,error))//" is invalid for a prolate spheroidal coordinate system."
          CALL flagerror(local_error,err,error,*999)
        END SELECT
      CASE(coordinate_oblate_spheroidal_type)
        CALL flagerror("Not implemented.",err,error,*999)
      CASE DEFAULT
        local_error="The coordinate system type of "//trim(number_to_vstring(coordinate_system%TYPE,"*",err,error))// &
          & " is invalid."
        CALL flagerror(local_error,err,error,*999)
      END SELECT
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF
      
    exits("COORDINATE_INTERPOLATION_ADJUST")
    RETURN
999 errorsexits("COORDINATE_INTERPOLATION_ADJUST",err,error)
    RETURN 1
  END SUBROUTINE coordinate_interpolation_adjust

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_interpolation_parameters_adjust(COORDINATE_SYSTEM,INTERPOLATION_PARAMETERS,ERR,ERROR,*)
  
    !Argument variables
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    TYPE(field_interpolation_parameters_type), POINTER :: INTERPOLATION_PARAMETERS
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local variables
    TYPE(varying_string) :: LOCAL_ERROR
    
    enters("COORDINATE_INTERPOLATION_PARAMETERS_ADJUST",err,error,*999)

!!TODO: Tidy up element parameters for non-rc coordinate systems. See bottom of XPXE and ZPZE.
    
    IF(ASSOCIATED(coordinate_system)) THEN
      IF(ASSOCIATED(interpolation_parameters)) THEN
        SELECT CASE(coordinate_system%TYPE)
        CASE(coordinate_rectangular_cartesian_type)
          !Do nothing
        CASE(coordinate_cylindrical_polar_type)
          SELECT CASE(coordinate_system%RADIAL_INTERPOLATION_TYPE)
          CASE(coordinate_radial_interpolation_type)
            !Do nothing
          CASE(coordinate_radial_squared_interpolation_type)
          CASE DEFAULT
            local_error="The radial interpolation type of "//trim(number_to_vstring(coordinate_system% &
              & radial_interpolation_type,"*",err,error))//" is invalid for a cylindrical coordinate system."
            CALL flagerror(local_error,err,error,*999)
          END SELECT
          CALL flagerror("Not implemented",err,error,*999)
        CASE(coordinate_spherical_polar_type)
          SELECT CASE(coordinate_system%RADIAL_INTERPOLATION_TYPE)
          CASE(coordinate_radial_interpolation_type)
            !Do nothing
          CASE(coordinate_radial_squared_interpolation_type)
          CASE DEFAULT
            local_error="The radial interpolation type of "//trim(number_to_vstring(coordinate_system% &
              & radial_interpolation_type,"*",err,error))//" is invalid for a spherical coordinate system."
            CALL flagerror(local_error,err,error,*999)
          END SELECT
          CALL flagerror("Not implemented.",err,error,*999)
        CASE(coordinate_prolate_spheroidal_type)
          SELECT CASE(coordinate_system%RADIAL_INTERPOLATION_TYPE)
          CASE(coordinate_radial_interpolation_type)
            !Do nothing
          CASE(coordinate_radial_squared_interpolation_type)
          CASE(coordinate_radial_cubed_interpolation_type)
          CASE DEFAULT
            local_error="The radial interpolation type of "//trim(number_to_vstring(coordinate_system% &
              & radial_interpolation_type,"*",err,error))//" is invalid for a prolate spheroidal coordinate system."
            CALL flagerror(local_error,err,error,*999)
          END SELECT
          CALL flagerror("Not implemented.",err,error,*999)
        CASE(coordinate_oblate_spheroidal_type)
          CALL flagerror("Not implemented.",err,error,*999)
        CASE DEFAULT
          local_error="The coordinate system type of "//trim(number_to_vstring(coordinate_system%TYPE,"*",err,error))// &
            & " is invalid."
          CALL flagerror(local_error,err,error,*999)
        END SELECT
      ELSE
        CALL flagerror("Interpolation parameters is not associated.",err,error,*999)
      ENDIF
    ELSE
      CALL flagerror("Coordinate system is not associated.",err,error,*999)
    ENDIF
      
    exits("COORDINATE_INTERPOLATION_PARAMETERS_ADJUST")
    RETURN
999 errorsexits("COORDINATE_INTERPOLATION_PARAMETERS_ADJUST",err,error)
    RETURN 1
  END SUBROUTINE coordinate_interpolation_parameters_adjust

  !
  !================================================================================================================================
  !
 
  SUBROUTINE coordinates_materialsystemcalculate(geometricInterpPointMetrics,fibreInterpPoint,dNudX,dXdNu,dNudXi,dXidNu,err,error,*)
  
    !Argument variables
    TYPE(field_interpolated_point_metrics_type), POINTER :: geometricInterpPointMetrics
    TYPE(field_interpolated_point_type), POINTER :: fibreInterpPoint
    REAL(DP), INTENT(OUT) :: dNudX(:,:)
    REAL(DP), INTENT(OUT) :: dXdNu(:,:)
    REAL(DP), INTENT(OUT) :: dNudXi(:,:)
    REAL(DP), INTENT(OUT) :: dXidNu(:,:)
    INTEGER(INTG), INTENT(OUT) :: err
    TYPE(varying_string), INTENT(OUT) ::  error
    !Local variables
    INTEGER(INTG) :: numberOfXDimensions,numberOfXiDimensions,numberOfNuDimensions,xiIdx
    REAL(DP) :: dNudXiTemp(3,3),Jnuxi
    TYPE(varying_string) :: localError 
     
    enters("Coordinates_MaterialSystemCalculate",err,error,*999)
    
    IF(ASSOCIATED(geometricinterppointmetrics)) THEN
      
      numberofxdimensions=geometricinterppointmetrics%NUMBER_OF_X_DIMENSIONS
      numberofxidimensions=geometricinterppointmetrics%NUMBER_OF_XI_DIMENSIONS
      
      !Calculate dX/dNu and its inverse dNu/dX (same as transpose due to orthogonality)
      
      !The fibre interpolated point might not be used for isotropic constitutive relations
      IF(ASSOCIATED(fibreinterppoint)) THEN
        !We have a fibre field
        numberofnudimensions=SIZE(fibreinterppoint%values,1)
        SELECT CASE(numberofxdimensions)
        CASE(1)
          dxdnu(1,1)=1.0_dp
        CASE(2)
          CALL coordinates_materialsystemcalculatedxdnu2d(geometricinterppointmetrics,fibreinterppoint%values(1: &
            & numberofnudimensions,1),dxdnu(1:numberofxdimensions,1:numberofxdimensions),err,error,*999)
        CASE(3)
          CALL coordinates_materialsystemcalculatedxdnu3d(geometricinterppointmetrics,fibreinterppoint%values(1: &
            & numberofnudimensions,1),dxdnu(1:numberofxdimensions,1:numberofxdimensions),err,error,*999)
        CASE DEFAULT
          localerror="The number of dimensions in the geometric interpolated point of "// &
            & trim(numbertovstring(numberofxdimensions,"*",err,error))// &
            & " is invalid. The number of dimensions must be >= 1 and <= 3."
          CALL flagerror(localerror,err,error,*999)
        END SELECT
      ELSE
        !No fibre field
        numberofnudimensions=0
        DO xiidx=1,numberofxidimensions
          dnudxitemp(1:numberofxdimensions,xiidx)=geometricinterppointmetrics%DX_DXI(1:numberofxdimensions,xiidx)
          dxdnu(1:numberofxdimensions,xiidx)=normalise(dnudxitemp(1:numberofxdimensions,xiidx),err,error)
        ENDDO !xiIdx
      ENDIF
      !Calculate dNu/dX the inverse of dX/dNu (same as transpose due to orthogonality)
      CALL matrixtranspose(dxdnu(1:numberofxdimensions,1:numberofxdimensions),dnudx(1:numberofxdimensions,1: &
        & numberofxdimensions),err,error,*999)
      !Calculate dNu/dXi = dNu/dX * dX/dXi and its inverse dXi/dNu
      CALL matrixproduct(dnudx(1:numberofxdimensions,1:numberofxdimensions), &
        & geometricinterppointmetrics%DX_DXI(1:numberofxdimensions,1:numberofxidimensions), &
        & dnudxitemp(1:numberofxdimensions,1:numberofxidimensions),err,error,*999)
      !Setup dNudXi
      CALL identitymatrix(dnudxi,err,error,*999)
      dnudxi(1:numberofxdimensions,1:numberofxidimensions)=dnudxitemp(1:numberofxdimensions,1:numberofxidimensions)

      IF(numberofxdimensions==numberofxidimensions) THEN
        CALL invert(dnudxi(1:numberofxdimensions,1:numberofxidimensions),dxidnu(1:numberofxidimensions,1:numberofxdimensions), &
          & jnuxi,err,error,*999)
      ELSE
        CALL flagerror("Not implemented",err,error,*999)
      ENDIF

      IF(diagnostics1) THEN
        CALL writestring(diagnostic_output_type,"",err,error,*999)
        CALL writestring(diagnostic_output_type,"Calculated material coordinate system:",err,error,*999)
        CALL writestringvalue(diagnostic_output_type,"  Number of X dimensions  = ",numberofxdimensions,err,error,*999)
        CALL writestringvalue(diagnostic_output_type,"  Number of Xi dimensions = ",numberofxidimensions,err,error,*999)
        CALL writestringvalue(diagnostic_output_type,"  Number of Nu dimensions = ",numberofnudimensions,err,error,*999)
        CALL writestring(diagnostic_output_type,"  Derivative of X wrt Nu:",err,error,*999)
        CALL writestringmatrix(diagnostic_output_type,1,1,numberofxdimensions,1,1,numberofxdimensions, &
          & numberofxdimensions,numberofxdimensions,dxdnu,write_string_matrix_name_and_indices, &
          & '("    dX_dNu','(",I1,",:)','  :",3(X,E13.6))','(18X,3(X,E13.6))',err,error,*999)
        CALL writestring(diagnostic_output_type,"  Derivative of Nu wrt X:",err,error,*999)
        CALL writestringmatrix(diagnostic_output_type,1,1,numberofxdimensions,1,1,numberofxdimensions, &
          & numberofxdimensions,numberofxdimensions,dnudx,write_string_matrix_name_and_indices, &
          & '("    dNu_dX','(",I1,",:)','  :",3(X,E13.6))','(18X,3(X,E13.6))',err,error,*999)
        CALL writestringvalue(diagnostic_output_type,"  Determinant dNu_dX, JNuX = ", &
          & determinant(dnudx(1:numberofxdimensions,1:numberofxdimensions),err,error),err,error,*999)
        CALL writestring(diagnostic_output_type,"  Derivative of Nu wrt Xi:",err,error,*999)
        CALL writestringmatrix(diagnostic_output_type,1,1,numberofxdimensions,1,1,numberofxidimensions, &
          & numberofxidimensions,numberofxidimensions,dnudxi,write_string_matrix_name_and_indices, &
          & '("    dNu_dXi','(",I1,",:)',' :",3(X,E13.6))','(18X,3(X,E13.6))',err,error,*999)
        CALL writestring(diagnostic_output_type,"  Derivative of Xi wrt Nu:",err,error,*999)
        CALL writestringmatrix(diagnostic_output_type,1,1,numberofxidimensions,1,1,numberofxdimensions, &
          & numberofxdimensions,numberofxdimensions,dxidnu,write_string_matrix_name_and_indices, &
          & '("    dXi_dNu','(",I1,",:)',' :",3(X,E13.6))','(18X,3(X,E13.6))',err,error,*999)
        CALL writestringvalue(diagnostic_output_type,"  Determinant dNu_dXi, JNuXi = ",jnuxi,err,error,*999)
      ENDIF
      
    ELSE
      CALL flagerror("Geometric interpolated point metrics is not associated.",err,error,*999)
    ENDIF    
    
    exits("Coordinates_MaterialSystemCalculate")
    RETURN
999 errorsexits("Coordinates_MaterialSystemCalculate",err,error)
    RETURN 1
    
  END SUBROUTINE coordinates_materialsystemcalculate
  
  !
  !================================================================================================================================
  !

  SUBROUTINE coordinates_materialsystemcalculatedxdnu2d(geometricInterpPointMetrics,angle,dXdNu,err,error,*)

    !Argument variables
    TYPE(field_interpolated_point_metrics_type), POINTER :: geometricInterpPointMetrics
    REAL(DP), INTENT(IN) :: angle(:)
    REAL(DP), INTENT(OUT) :: dXdNu(:,:)
    INTEGER(INTG), INTENT(OUT) :: err
    TYPE(varying_string), INTENT(OUT) :: error
    !Local Variables
    REAL(DP) :: det,dXdNuR(2,2),R(2,2),f(2),g(2)

    enters("Coordinates_MaterialSystemCalculatedXdNu2D",err,error,*999)

    IF(ASSOCIATED(geometricinterppointmetrics)) THEN
    
      !First calculate reference material CS
      
      !Reference material direction 1.
      f(1:2) = [ geometricinterppointmetrics%DX_DXI(1,1),geometricinterppointmetrics%DX_DXI(2,1) ]
      
      !Compute (normalised) vector orthogonal to material direction 1 to form material direction 2
      g(1:2) = [ -1.0_dp*f(2),f(1) ]
      
      dxdnur(1:2,1) = normalise(f(1:2),err,error)
      IF(err/=0) GOTO 999
      dxdnur(1:2,2) = normalise(g(1:2),err,error)
      IF(err/=0) GOTO 999
      
      !Rotate by multiply with rotation matrix
      r(:,1) = [ cos(angle(1)),-1.0_dp*sin(angle(1)) ]
      r(:,2) = [ sin(angle(1)),cos(angle(1)) ]
      
      CALL matrixproduct(r,dxdnur,dxdnu,err,error,*999)
      
      dxdnu(1:2,1) = normalise(dxdnu(1:2,1),err,error)
      IF(err/=0) GOTO 999
      dxdnu(1:2,2) = normalise(dxdnu(1:2,2),err,error)
      IF(err/=0) GOTO 999

      IF(diagnostics1) THEN
        CALL writestring(diagnostic_output_type,"",err,error,*999)
        CALL writestring(diagnostic_output_type,"2D material system calculation:",err,error,*999)
        CALL writestring(diagnostic_output_type,"  Reference material directions:",err,error,*999)
        CALL writestringvector(diagnostic_output_type,1,1,2,2,2,f,'("    f              :",2(X,E13.6))','(20X,2(X,E13.6))', &
          & err,error,*999)      
        CALL writestringvector(diagnostic_output_type,1,1,2,2,2,g,'("    g              :",2(X,E13.6))','(20X,2(X,E13.6))', &
          & err,error,*999)      
        CALL writestring(diagnostic_output_type,"    Derivative of X wrt Nu (reference):",err,error,*999)
        CALL writestringmatrix(diagnostic_output_type,1,1,2,1,1,2,2,2,dxdnur,write_string_matrix_name_and_indices, &
          & '("      dX_dNuR','(",I1,",:)',' :",2(X,E13.6))','(20X,2(X,E13.6))',err,error,*999)
        CALL writestring(diagnostic_output_type,"  Fibre calculation:",err,error,*999)
        CALL writestringvalue(diagnostic_output_type,"    Fibre angle = ",angle(1),err,error,*999)
        IF(diagnostics2) THEN
          CALL writestring(diagnostic_output_type,"    Rotation matrix:",err,error,*999)
          CALL writestringmatrix(diagnostic_output_type,1,1,2,1,1,2,2,2,r,write_string_matrix_name_and_indices, &
            & '("      R','(",I1,",:)','       :",2(X,E13.6))','(20X,2(X,E13.6))',err,error,*999)
        ENDIF
        CALL writestring(diagnostic_output_type,"    Derivative of X wrt Nu (material):",err,error,*999)
        CALL writestringmatrix(diagnostic_output_type,1,1,2,1,1,2,2,2,dxdnu,write_string_matrix_name_and_indices, &
          & '("      dX_dNu','(",I1,",:)','   :",2(X,E13.6))','(20X,2(X,E13.6))',err,error,*999)
        det=determinant(dxdnu,err,error)
        CALL writestringvalue(diagnostic_output_type,"    Determinant dX_dNu = ",det,err,error,*999)
      ENDIF
      
    ELSE
      CALL flagerror("Geometry interpolated point metrics is not associated.",err,error,*999)
    ENDIF
        
    exits("Coordinates_MaterialSystemCalculatedXdNu2D")
    RETURN
999 errorsexits("Coordinates_MaterialSystemCalculatedXdNu2D",err,error)
    RETURN 1
    
  END SUBROUTINE coordinates_materialsystemcalculatedxdnu2d

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinates_materialsystemcalculatedxdnu3d(geometricInterpPointMetrics,angle,dXdNu,err,error,*)

    !Argument variables
    TYPE(field_interpolated_point_metrics_type), POINTER :: geometricInterpPointMetrics
    REAL(DP), INTENT(IN) :: angle(:)
    REAL(DP), INTENT(OUT) :: dXdNu(:,:)
    INTEGER(INTG), INTENT(OUT) :: err
    TYPE(varying_string), INTENT(OUT) :: error
    !Local Variables
    REAL(DP) :: angles(3),det,dXdNu2(3,3),dXdNu3(3,3),dXdNuR(3,3),f(3),g(3),h(3), &
      & Raf(3,3),Rbf(3,3),Rai(3,3),Rbi(3,3),Ras(3,3),Rbs(3,3)
    
    enters("Coordinates_MaterialSystemCalculatedXdNu3D",err,error,*999)
    
    IF(ASSOCIATED(geometricinterppointmetrics)) THEN

      !Calculate fibre, imbrication and sheet angles (allowing for missing angles)
      angles=0.0_dp
      angles(1:SIZE(angle,1))=angle(1:SIZE(angle,1))
      
      !First calculate reference material CS
      f(1:3)=geometricinterppointmetrics%DX_DXI(1:3,1) !reference material direction 1.
      CALL crossproduct(geometricinterppointmetrics%DX_DXI(1:3,1),geometricinterppointmetrics%DX_DXI(1:3,2),h,err,error,*999) !reference material direction 3.    
      CALL crossproduct(h,f,g,err,error,*999) !reference material direction 2.      

      dxdnur(1:3,1)=normalise(f,err,error)
      IF(err/=0) GOTO 999
      dxdnur(1:3,2)=normalise(g,err,error)
      IF(err/=0) GOTO 999
      dxdnur(1:3,3)=normalise(h,err,error)
      IF(err/=0) GOTO 999
      
      IF(diagnostics1) THEN
      ENDIF

      !FIBRE ANGLE(alpha) - angles(1) 
      !In order to rotate reference material CS by alpha(fibre angle) in anti-clockwise  
      !direction about its axis 3, following steps are performed.
      !(a) first align reference material direction 3 with Z(spatial) axis by rotating the ref material CS. 
      !(b) then rotate the aligned material CS by alpha about Z axis in anti-clockwise direction
      !(c) apply the inverse of step(a) to the CS in (b)
      !It can be shown that steps (a),(b) and (c) are equivalent to post-multiplying
      !rotation in (a) by rotation in (b). i.e. Ra*Rb  
      
      !The normalised reference material CS contains the transformation(rotation) between 
      !the spatial CS -> reference material CS. i.e. Raf
      raf=dxdnur
        
      !Initialise rotation matrix Rbf
      CALL identitymatrix(rbf,err,error,*999)
      !Populate rotation matrix Rbf about axis 3 (Z)
      rbf(1,1)=cos(angles(1))
      rbf(1,2)=-1.0_dp*sin(angles(1))
      rbf(2,1)=sin(angles(1))
      rbf(2,2)=cos(angles(1))
        
      CALL matrixproduct(raf,rbf,dxdnu3,err,error,*999)  

      !IMBRICATION ANGLE (beta) - angles(2)     
      !In order to rotate alpha-rotated material CS by beta(imbrication angle) in anti-clockwise  
      !direction about its new axis 2, following steps are performed.
      !(a) first align new material direction 2 with Y(spatial) axis by rotating the new material CS. 
      !(b) then rotate the aligned CS by beta about Y axis in anti-clockwise direction
      !(c) apply the inverse of step(a) to the CS in (b)
      !As mentioned above, (a),(b) and (c) are equivalent to post-multiplying
      !rotation in (a) by rotation in (b). i.e. Rai*Rbi  
      
      !dXdNu3 contains the transformation(rotation) between 
      !the spatial CS -> alpha-rotated reference material CS. i.e. Rai
      rai=dxdnu3
      !Initialise rotation matrix Rbi
      CALL identitymatrix(rbi,err,error,*999)
      !Populate rotation matrix Rbi about axis 2 (Y). Note the sign change
      rbi(1,1)=cos(angles(2))
      rbi(1,3)=sin(angles(2))
      rbi(3,1)=-1.0_dp*sin(angles(2))
      rbi(3,3)=cos(angles(2))
        
      CALL matrixproduct(rai,rbi,dxdnu2,err,error,*999)  

      !SHEET ANGLE (gamma) - angles(3)    
      !In order to rotate alpha-beta-rotated material CS by gama(sheet angle) in anti-clockwise  
      !direction about its new axis 1, following steps are performed.
      !(a) first align new material direction 1 with X(spatial) axis by rotating the new material CS. 
      !(b) then rotate the aligned CS by gama about X axis in anti-clockwise direction
      !(c) apply the inverse of step(a) to the CS in (b)
      !Again steps (a),(b) and (c) are equivalent to post-multiplying
      !rotation in (a) by rotation in (b). i.e. Ras*Rbs  
      
      !dXdNu2 contains the transformation(rotation) between 
      !the spatial CS -> alpha-beta-rotated reference material CS. i.e. Ras
      ras=dxdnu2
      !Initialise rotation matrix Rbs
      CALL identitymatrix(rbs,err,error,*999)
      !Populate rotation matrix Rbs about axis 1 (X). 
      rbs(2,2)=cos(angles(3))
      rbs(2,3)=-1.0_dp*sin(angles(3))
      rbs(3,2)=sin(angles(3))
      rbs(3,3)=cos(angles(3))
      
      CALL matrixproduct(ras,rbs,dxdnu,err,error,*999)  

      IF(diagnostics1) THEN
        CALL writestring(diagnostic_output_type,"",err,error,*999)
        CALL writestring(diagnostic_output_type,"3D material system calculation:",err,error,*999)
        CALL writestring(diagnostic_output_type,"  Reference material directions:",err,error,*999)
        CALL writestringvector(diagnostic_output_type,1,1,3,3,3,f,'("    f              :",3(X,E13.6))','(20X,3(X,E13.6))', &
          & err,error,*999)      
        CALL writestringvector(diagnostic_output_type,1,1,3,3,3,g,'("    g              :",3(X,E13.6))','(20X,3(X,E13.6))', &
          & err,error,*999)      
        CALL writestringvector(diagnostic_output_type,1,1,3,3,3,h,'("    h              :",3(X,E13.6))','(20X,3(X,E13.6))', &
          & err,error,*999)      
        CALL writestring(diagnostic_output_type,"    Derivative of X wrt Nu (reference):",err,error,*999)
        CALL writestringmatrix(diagnostic_output_type,1,1,3,1,1,3,3,3,dxdnur,write_string_matrix_name_and_indices, &
          & '("      dX_dNuR','(",I1,",:)',' :",3(X,E13.6))','(20X,3(X,E13.6))',err,error,*999)
        CALL writestring(diagnostic_output_type,"  Fibre calculation:",err,error,*999)
        CALL writestringvalue(diagnostic_output_type,"    Fibre angle = ",angles(1),err,error,*999)
        IF(diagnostics2) THEN
          CALL writestring(diagnostic_output_type,"    Rotation matrix A:",err,error,*999)
          CALL writestringmatrix(diagnostic_output_type,1,1,3,1,1,3,3,3,raf,write_string_matrix_name_and_indices, &
            & '("      Ra','(",I1,",:)','      :",3(X,E13.6))','(20X,3(X,E13.6))',err,error,*999)
          CALL writestring(diagnostic_output_type,"    Rotation matrix B:",err,error,*999)
          CALL writestringmatrix(diagnostic_output_type,1,1,3,1,1,3,3,3,rbf,write_string_matrix_name_and_indices, &
            & '("      Rb','(",I1,",:)','      :",3(X,E13.6))','(20X,3(X,E13.6))',err,error,*999)
        ENDIF
        CALL writestring(diagnostic_output_type,"    Derivative of X wrt Nu (after alpha rotation):",err,error,*999)
        CALL writestringmatrix(diagnostic_output_type,1,1,3,1,1,3,3,3,dxdnu3,write_string_matrix_name_and_indices, &
          & '("      dX_dNu3','(",I1,",:)',' :",3(X,E13.6))','(20X,3(X,E13.6))',err,error,*999)
        CALL writestring(diagnostic_output_type,"  Imbrication calculation:",err,error,*999)
        CALL writestringvalue(diagnostic_output_type,"    Imbrication angle = ",angles(2),err,error,*999)
        IF(diagnostics2) THEN
          CALL writestring(diagnostic_output_type,"    Rotation matrix A:",err,error,*999)
          CALL writestringmatrix(diagnostic_output_type,1,1,3,1,1,3,3,3,rai,write_string_matrix_name_and_indices, &
            & '("      Ra','(",I1,",:)','      :",3(X,E13.6))','(20X,3(X,E13.6))',err,error,*999)
          CALL writestring(diagnostic_output_type,"    Rotation matrix B:",err,error,*999)
          CALL writestringmatrix(diagnostic_output_type,1,1,3,1,1,3,3,3,rbi,write_string_matrix_name_and_indices, &
            & '("      Rb','(",I1,",:)','      :",3(X,E13.6))','(20X,3(X,E13.6))',err,error,*999)
        ENDIF
        CALL writestring(diagnostic_output_type,"    Derivative of X wrt Nu (after alpha-beta rotation):",err,error,*999)
        CALL writestringmatrix(diagnostic_output_type,1,1,3,1,1,3,3,3,dxdnu2,write_string_matrix_name_and_indices, &
          & '("      dX_dNu2','(",I1,",:)',' :",3(X,E13.6))','(20X,3(X,E13.6))',err,error,*999)
         CALL writestring(diagnostic_output_type,"  Sheet calculation:",err,error,*999)
        CALL writestringvalue(diagnostic_output_type,"    Sheet angle = ",angles(3),err,error,*999)
        IF(diagnostics2) THEN
          CALL writestring(diagnostic_output_type,"    Rotation matrix A:",err,error,*999)
          CALL writestringmatrix(diagnostic_output_type,1,1,3,1,1,3,3,3,ras,write_string_matrix_name_and_indices, &
            & '("      Ra','(",I1,",:)','      :",3(X,E13.6))','(20X,3(X,E13.6))',err,error,*999)
          CALL writestring(diagnostic_output_type,"    Rotation matrix B:",err,error,*999)
          CALL writestringmatrix(diagnostic_output_type,1,1,3,1,1,3,3,3,rbs,write_string_matrix_name_and_indices, &
            & '("      Rb','(",I1,",:)','      :",3(X,E13.6))','(20X,3(X,E13.6))',err,error,*999)
        ENDIF
        CALL writestring(diagnostic_output_type,"    Derivative of X wrt Nu (material):",err,error,*999)
        CALL writestringmatrix(diagnostic_output_type,1,1,3,1,1,3,3,3,dxdnu,write_string_matrix_name_and_indices, &
          & '("      dX_dNu','(",I1,",:)','  :",3(X,E13.6))','(20X,3(X,E13.6))',err,error,*999)
        det=determinant(dxdnu,err,error)
        CALL writestringvalue(diagnostic_output_type,"    Determinant dX_dNu = ",det,err,error,*999)
      ENDIF
            
    ELSE
      CALL flagerror("Geometry interpolated point metrics is not associated.",err,error,*999)
    ENDIF
    
    exits("Coordinates_MaterialSystemCalculatedXdNu3D")
    RETURN
999 errorsexits("Coordinates_MaterialSystemCalculatedXdNu3D",err,error)
    RETURN 1
    
  END SUBROUTINE coordinates_materialsystemcalculatedxdnu3d

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_system_user_number_find(USER_NUMBER,COORDINATE_SYSTEM,ERR,ERROR,*)

    !Argument variables
    INTEGER(INTG), INTENT(IN) :: USER_NUMBER
    TYPE(coordinate_system_type), POINTER :: COORDINATE_SYSTEM
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables
    INTEGER(INTG) :: coord_system_idx
    
    enters("COORDINATE_SYSTEM_USER_NUMBER_FIND",err,error,*999)

    IF(ASSOCIATED(coordinate_system)) THEN
      CALL flagerror("Coordinate_system is already associated.",err,error,*999)
    ELSE
      NULLIFY(coordinate_system)
      coord_system_idx=1
      DO WHILE(coord_system_idx<=coordinate_systems%NUMBER_OF_COORDINATE_SYSTEMS.AND..NOT.ASSOCIATED(coordinate_system))
        IF(coordinate_systems%COORDINATE_SYSTEMS(coord_system_idx)%PTR%USER_NUMBER==user_number) THEN
          coordinate_system=>coordinate_systems%COORDINATE_SYSTEMS(coord_system_idx)%PTR
        ELSE
          coord_system_idx=coord_system_idx+1
        ENDIF
      ENDDO
    ENDIF
    
    exits("COORDINATE_SYSTEM_USER_NUMBER_FIND")
    RETURN
999 errorsexits("COORDINATE_SYSTEM_USER_NUMBER_FIND",err,error)
    RETURN 1
  END SUBROUTINE coordinate_system_user_number_find

  !
  !================================================================================================================================
  !

  SUBROUTINE coordinate_systems_finalise(ERR,ERROR,*)

    !Argument variables
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables
    INTEGER(INTG) :: coord_system_idx
    
    enters("COORDINATE_SYSTEMS_FINALISE",err,error,*999)

    DO coord_system_idx=1,coordinate_systems%NUMBER_OF_COORDINATE_SYSTEMS
      CALL coordinate_system_finalise(coordinate_systems%COORDINATE_SYSTEMS(coord_system_idx)%PTR,err,error,*999)
    ENDDO !coord_system_idx
    DEALLOCATE(coordinate_systems%COORDINATE_SYSTEMS)
    coordinate_systems%NUMBER_OF_COORDINATE_SYSTEMS=0
    
    exits("COORDINATE_SYSTEMS_FINALISE")
    RETURN
999 errorsexits("COORDINATE_SYSTEMS_FINALISE",err,error)
    RETURN 1
  END SUBROUTINE coordinate_systems_finalise

  !
  !================================================================================================================================
  !
   
  SUBROUTINE coordinate_systems_initialise(ERR,ERROR,*)

    !Argument variables
    INTEGER(INTG), INTENT(OUT) :: ERR
    TYPE(varying_string), INTENT(OUT) :: ERROR
    !Local Variables
    
    enters("COORDINATE_SYSTEMS_INITIALISE",err,error,*999)

    !Allocate the coordinate systems
    ALLOCATE(coordinate_systems%COORDINATE_SYSTEMS(1),stat=err)
    IF(err/=0) CALL flagerror("Could not allocate coordinate systems.",err,error,*999)
    !Create the default RC World cooordinate system
    ALLOCATE(coordinate_systems%COORDINATE_SYSTEMS(1)%PTR,stat=err)
    IF(err/=0) CALL flagerror("Could not allocate world coordinate system.",err,error,*999)
    coordinate_systems%COORDINATE_SYSTEMS(1)%PTR%USER_NUMBER=0
    coordinate_systems%COORDINATE_SYSTEMS(1)%PTR%TYPE=coordinate_rectangular_cartesian_type
    coordinate_systems%COORDINATE_SYSTEMS(1)%PTR%NUMBER_OF_DIMENSIONS=3
    coordinate_systems%COORDINATE_SYSTEMS(1)%PTR%FOCUS=1.0_dp    
    coordinate_systems%COORDINATE_SYSTEMS(1)%PTR%ORIGIN=(/0.0_dp,0.0_dp,0.0_dp/)
    coordinate_systems%COORDINATE_SYSTEMS(1)%PTR%ORIENTATION=reshape(&
      & (/1.0_dp,0.0_dp,0.0_dp, &
      &   0.0_dp,1.0_dp,0.0_dp, &
      &   0.0_dp,0.0_dp,1.0_dp/), &
      & (/3,3/))    
    coordinate_systems%COORDINATE_SYSTEMS(1)%PTR%COORDINATE_SYSTEM_FINISHED=.true.
    coordinate_systems%NUMBER_OF_COORDINATE_SYSTEMS=1
   
    exits("COORDINATE_SYSTEMS_INITIALISE")
    RETURN
999 errorsexits("COORDINATE_SYSTEMS_INITIALISE",err,error)
    RETURN 1
  END SUBROUTINE coordinate_systems_initialise

  !
  !================================================================================================================================
  !
  
END MODULE coordinate_routines