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new_tsdadg_pdf.F90
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! $Id$
!===============================================================================
module new_tsdadg_pdf
! Description:
! The new trivariate, skewness-dependent, analytic double Gaussian (TSDADG)
! PDF.
implicit none
public :: tsdadg_pdf_driver, & ! Procedure(s)
calc_setter_parameters, &
calc_L_x_Skx_fnc
private :: calc_respnder_parameters ! Procedure(s)
private ! default scope
contains
!=============================================================================
subroutine tsdadg_pdf_driver( wm, rtm, thlm, wp2, rtp2, thlp2, & ! In
Skw, Skrt, Skthl, wprtp, wpthlp, & ! In
mu_w_1, mu_w_2, & ! Out
mu_rt_1, mu_rt_2, & ! Out
mu_thl_1, mu_thl_2, & ! Out
sigma_w_1_sqd, sigma_w_2_sqd, & ! Out
sigma_rt_1_sqd, sigma_rt_2_sqd, & ! Out
sigma_thl_1_sqd, sigma_thl_2_sqd, & ! Out
mixt_frac ) ! Out
! Description:
! Selects which variable is used to set the mixture fraction for the PDF
! ("the setter") and which variables are handled after that mixture fraction
! has been set ("the responders"). Traditionally, w has been used to set
! the PDF. However, here, the variable with the greatest magnitude of
! skewness is used to set the PDF.
! References:
!-----------------------------------------------------------------------
use grid_class, only: &
gr ! Variable type(s)
use constants_clubb, only: &
one, & ! Variable(s)
zero, &
fstderr
use clubb_precision, only: &
core_rknd ! Variable(s)
implicit none
! Input Variables
real( kind = core_rknd ), dimension(gr%nz), intent(in) :: &
wm, & ! Mean of w (overall) [m/s]
rtm, & ! Mean of rt (overall) [kg/kg]
thlm, & ! Mean of thl (overall) [K]
wp2, & ! Variance of w (overall) [m^2/s^2]
rtp2, & ! Variance of rt (overall) [kg^2/kg^2]
thlp2, & ! Variance of thl (overall) [K^2]
Skw, & ! Skewness of w (overall) [-]
Skrt, & ! Skewness of rt (overall) [-]
Skthl, & ! Skewness of thl (overall) [-]
wprtp, & ! Covariance of w and rt (overall) [(m/s)kg/kg]
wpthlp ! Covariance of w and thl (overall) [(m/s)K]
! Output Variables
real( kind = core_rknd ), dimension(gr%nz), intent(out) :: &
mu_w_1, & ! Mean of w (1st PDF component) [m/s]
mu_w_2, & ! Mean of w (2nd PDF component) [m/s]
mu_rt_1, & ! Mean of rt (1st PDF component) [kg/kg]
mu_rt_2, & ! Mean of rt (2nd PDF component) [kg/kg]
mu_thl_1, & ! Mean of thl (1st PDF component) [K]
mu_thl_2, & ! Mean of thl (2nd PDF component) [K]
sigma_w_1_sqd, & ! Variance of w (1st PDF component) [m^2/s^2]
sigma_w_2_sqd, & ! Variance of w (2nd PDF component) [m^2/s^2]
sigma_rt_1_sqd, & ! Variance of rt (1st PDF component) [kg^2/kg^2]
sigma_rt_2_sqd, & ! Variance of rt (2nd PDF component) [kg^2/kg^2]
sigma_thl_1_sqd, & ! Variance of thl (1st PDF component) [K^2]
sigma_thl_2_sqd, & ! Variance of thl (2nd PDF component) [K^2]
mixt_frac ! Mixture fraction [-]
! Local Variables
real( kind = core_rknd ), dimension(gr%nz) :: &
big_L_w_1, & ! Parameter for the 1st PDF comp. mean of w [-]
big_L_w_2, & ! Parameter for the 2nd PDF comp. mean of w (setter) [-]
big_L_rt_1, & ! Parameter for the 1st PDF comp. mean of rt [-]
big_L_rt_2, & ! Parameter for the 2nd PDF comp. mean of rt (setter) [-]
big_L_thl_1, & ! Parameter for the 1st PDF comp. mean of thl [-]
big_L_thl_2 ! Parameter for the 2nd PDF comp. mean of thl (setter) [-]
real( kind = core_rknd ) :: &
small_l_w_1, & ! Param. for the 1st PDF comp. mean of w [-]
small_l_w_2, & ! Param. for the 2nd PDF comp. mean of w (setter) [-]
small_l_rt_1, & ! Param. for the 1st PDF comp. mean of rt [-]
small_l_rt_2, & ! Param. for the 2nd PDF comp. mean of rt (setter) [-]
small_l_thl_1, & ! Param. for the 1st PDF comp. mean of thl [-]
small_l_thl_2 ! Param. for the 2nd PDF comp. mean of thl (setter) [-]
real( kind = core_rknd ), dimension(gr%nz) :: &
sgn_wprtp, & ! Sign of the covariance of w and rt (overall) [-]
sgn_wpthlp, & ! Sign of the covariance of w and thl (overall) [-]
sgn_wp2 ! Sign of the variance of w (overall); always positive [-]
real( kind = core_rknd ), dimension(gr%nz) :: &
coef_sigma_w_1_sqd, & ! sigma_w_1^2 = coef_sigma_w_1_sqd * <w'^2> [-]
coef_sigma_w_2_sqd, & ! sigma_w_2^2 = coef_sigma_w_2_sqd * <w'^2> [-]
coef_sigma_rt_1_sqd, & ! sigma_rt_1^2 = coef_sigma_rt_1_sqd * <rt'^2> [-]
coef_sigma_rt_2_sqd, & ! sigma_rt_2^2 = coef_sigma_rt_2_sqd * <rt'^2> [-]
coef_sigma_thl_1_sqd, & ! sigma_thl_1^2=coef_sigma_thl_1_sqd*<thl'^2> [-]
coef_sigma_thl_2_sqd ! sigma_thl_2^2=coef_sigma_thl_2_sqd*<thl'^2> [-]
integer :: k ! Vertical level loop index
! Calculate sgn( <w'rt'> ).
where ( wprtp >= zero )
sgn_wprtp = one
elsewhere ! wprtp < 0
sgn_wprtp = -one
endwhere ! wprtp >= 0
! Calculate sgn( <w'thl'> ).
where ( wpthlp >= zero )
sgn_wpthlp = one
elsewhere ! wpthlp < 0
sgn_wpthlp = -one
endwhere ! wpthlp >= 0
! The sign of the variance of w is always positive.
sgn_wp2 = one
small_l_w_1 = 0.75_core_rknd
small_l_w_2 = 0.5_core_rknd
small_l_rt_1 = 0.75_core_rknd
small_l_rt_2 = 0.5_core_rknd
small_l_thl_1 = 0.75_core_rknd
small_l_thl_2 = 0.5_core_rknd
do k = 1, gr%nz, 1
call calc_L_x_Skx_fnc( Skw(k), sgn_wp2(k), & ! In
small_l_w_1, small_l_w_2, & ! In
big_L_w_1(k), big_L_w_2(k) ) ! Out
call calc_L_x_Skx_fnc( Skrt(k), sgn_wprtp(k), & ! In
small_l_rt_1, small_l_rt_2, & ! In
big_L_rt_1(k), big_L_rt_2(k) ) ! Out
call calc_L_x_Skx_fnc( Skthl(k), sgn_wpthlp(k), & ! In
small_l_thl_1, small_l_thl_2, & ! In
big_L_thl_1(k), big_L_thl_2(k) ) ! Out
! The variable with the greatest magnitude of skewness will be the setter
! variable and the other variables will be responder variables.
if ( abs( Skw(k) ) >= abs( Skrt(k) ) &
.and. abs( Skw(k) ) >= abs( Skthl(k) ) ) then
! The variable w has the greatest magnitude of skewness.
call calc_setter_parameters( wm(k), wp2(k), & ! In
Skw(k), sgn_wp2(k), & ! In
big_L_w_1(k), big_L_w_2(k), & ! In
mu_w_1(k), mu_w_2(k), & ! Out
sigma_w_1_sqd(k), & ! Out
sigma_w_2_sqd(k), mixt_frac(k), & ! Out
coef_sigma_w_1_sqd(k), & ! Out
coef_sigma_w_2_sqd(k) ) ! Out
call calc_respnder_parameters( rtm(k), rtp2(k), & ! In
Skrt(k), sgn_wprtp(k), & ! In
mixt_frac(k), big_L_rt_1(k), & ! In
mu_rt_1(k), mu_rt_2(k), & ! Out
sigma_rt_1_sqd(k), & ! Out
sigma_rt_2_sqd(k), & ! Out
coef_sigma_rt_1_sqd(k), & ! Out
coef_sigma_rt_2_sqd(k) ) ! Out
call calc_respnder_parameters( thlm(k), thlp2(k), & ! In
Skthl(k), sgn_wpthlp(k), & ! In
mixt_frac(k), big_L_thl_1(k), & ! In
mu_thl_1(k), mu_thl_2(k), & ! Out
sigma_thl_1_sqd(k), & ! Out
sigma_thl_2_sqd(k), & ! Out
coef_sigma_thl_1_sqd(k), & ! Out
coef_sigma_thl_2_sqd(k) ) ! Out
elseif ( abs( Skrt(k) ) > abs( Skw(k) ) &
.and. abs( Skrt(k) ) >= abs( Skthl(k) ) ) then
! The variable rt has the greatest magnitude of skewness.
call calc_setter_parameters( rtm(k), rtp2(k), & ! In
Skrt(k), sgn_wprtp(k), & ! In
big_L_rt_1(k), big_L_rt_2(k), & ! In
mu_rt_1(k), mu_rt_2(k), & ! Out
sigma_rt_1_sqd(k), & ! Out
sigma_rt_2_sqd(k), mixt_frac(k), & ! Out
coef_sigma_rt_1_sqd(k), & ! Out
coef_sigma_rt_2_sqd(k) ) ! Out
call calc_respnder_parameters( wm(k), wp2(k), & ! In
Skw(k), sgn_wp2(k), & ! In
mixt_frac(k), big_L_w_1(k), & ! In
mu_w_1(k), mu_w_2(k), & ! Out
sigma_w_1_sqd(k), & ! Out
sigma_w_2_sqd(k), & ! Out
coef_sigma_w_1_sqd(k), & ! Out
coef_sigma_w_2_sqd(k) ) ! Out
call calc_respnder_parameters( thlm(k), thlp2(k), & ! In
Skthl(k), sgn_wpthlp(k), & ! In
mixt_frac(k), big_L_thl_1(k), & ! In
mu_thl_1(k), mu_thl_2(k), & ! Out
sigma_thl_1_sqd(k), & ! Out
sigma_thl_2_sqd(k), & ! Out
coef_sigma_thl_1_sqd(k), & ! Out
coef_sigma_thl_2_sqd(k) ) ! Out
else ! abs( Skthl ) > abs( Skw ) .and. abs( Skthl ) > abs( Skrt )
! The variable thl has the greatest magnitude of skewness.
call calc_setter_parameters( thlm(k), thlp2(k), & ! In
Skthl(k), sgn_wpthlp(k), & ! In
big_L_thl_1(k), big_L_thl_2(k), & ! In
mu_thl_1(k), mu_thl_2(k), & ! Out
sigma_thl_1_sqd(k), & ! Out
sigma_thl_2_sqd(k), mixt_frac(k), & ! Out
coef_sigma_thl_1_sqd(k), & ! Out
coef_sigma_thl_2_sqd(k) ) ! Out
call calc_respnder_parameters( wm(k), wp2(k), & ! In
Skw(k), sgn_wp2(k), & ! In
mixt_frac(k), big_L_w_1(k), & ! In
mu_w_1(k), mu_w_2(k), & ! Out
sigma_w_1_sqd(k), & ! Out
sigma_w_2_sqd(k), & ! Out
coef_sigma_w_1_sqd(k), & ! Out
coef_sigma_w_2_sqd(k) ) ! Out
call calc_respnder_parameters( rtm(k), rtp2(k), & ! In
Skrt(k), sgn_wprtp(k), & ! In
mixt_frac(k), big_L_rt_1(k), & ! In
mu_rt_1(k), mu_rt_2(k), & ! Out
sigma_rt_1_sqd(k), & ! Out
sigma_rt_2_sqd(k), & ! Out
coef_sigma_rt_1_sqd(k), & ! Out
coef_sigma_rt_2_sqd(k) ) ! Out
endif ! Find variable with the greatest magnitude of skewness.
if ( sigma_w_1_sqd(k) < zero ) then
write(fstderr,*) "WARNING: New TSDADG PDF. The variance of w in " &
// "the 1st PDF component is negative and is " &
// "being clipped to 0."
write(fstderr,*) "sigma_w_1^2 (before clipping) = ", sigma_w_1_sqd(k)
sigma_w_1_sqd(k) = zero
coef_sigma_w_1_sqd(k) = zero
endif ! sigma_w_1_sqd < 0
if ( sigma_w_2_sqd(k) < zero ) then
write(fstderr,*) "WARNING: New TSDADG PDF. The variance of w in " &
// "the 2nd PDF component is negative and is " &
// "being clipped to 0."
write(fstderr,*) "sigma_w_2^2 (before clipping) = ", sigma_w_2_sqd(k)
sigma_w_2_sqd(k) = zero
coef_sigma_w_2_sqd(k) = zero
endif ! sigma_w_2_sqd < 0
if ( sigma_rt_1_sqd(k) < zero ) then
write(fstderr,*) "WARNING: New TSDADG PDF. The variance of rt in " &
// "the 1st PDF component is negative and is " &
// "being clipped to 0."
write(fstderr,*) "sigma_rt_1^2 (before clipping) = ", &
sigma_rt_1_sqd(k)
sigma_rt_1_sqd(k) = zero
coef_sigma_rt_1_sqd(k) = zero
endif ! sigma_rt_1_sqd < 0
if ( sigma_rt_2_sqd(k) < zero ) then
write(fstderr,*) "WARNING: New TSDADG PDF. The variance of rt in " &
// "the 2nd PDF component is negative and is " &
// "being clipped to 0."
write(fstderr,*) "sigma_rt_2^2 (before clipping) = ", &
sigma_rt_2_sqd(k)
sigma_rt_2_sqd(k) = zero
coef_sigma_rt_2_sqd(k) = zero
endif ! sigma_rt_2_sqd < 0
if ( sigma_thl_1_sqd(k) < zero ) then
write(fstderr,*) "WARNING: New TSDADG PDF. The variance of thl " &
// "in the 1st PDF component is negative and is " &
// "being clipped to 0."
write(fstderr,*) "sigma_thl_1^2 (before clipping) = ", &
sigma_thl_1_sqd(k)
sigma_thl_1_sqd(k) = zero
coef_sigma_thl_1_sqd(k) = zero
endif ! sigma_thl_1_sqd < 0
if ( sigma_thl_2_sqd(k) < zero ) then
write(fstderr,*) "WARNING: New TSDADG PDF. The variance of thl " &
// "in the 2nd PDF component is negative and is " &
// "being clipped to 0."
write(fstderr,*) "sigma_thl_2^2 (before clipping) = ", &
sigma_thl_2_sqd(k)
sigma_thl_2_sqd(k) = zero
coef_sigma_thl_2_sqd(k) = zero
endif ! sigma_thl_2_sqd < 0
enddo ! k = 1, gr%nz, 1
return
end subroutine tsdadg_pdf_driver
!=============================================================================
!
! DESCRIPTION OF THE METHOD FOR THE VARIABLE THAT SETS THE MIXTURE FRACTION
! =========================================================================
!
! There are five PDF parameters that need to be calculated for the setting
! variable, which are mu_x_1 (the mean of x in the 1st PDF component), mu_x_2
! (the mean of x in the 2nd PDF component), sigma_x_1 (the standard deviation
! of x in the 1st PDF component), sigma_x_2 (the standard deviation of x in
! the 2nd PDF component), and mixt_frac (the mixture fraction). In order to
! solve for these five parameters, five equations are needed. These five
! equations are the equations for <x>, <x'^2>, and <x'^3> as found by
! integrating over the PDF. Additionally, two more equations, which involve
! tunable parameters L_x_1 and L_x_2, and which are used to help control the
! spread of the PDF component means in the 1st PDF component and the 2nd PDF
! component, respectively, are used in this equation set. The five equations
! are:
!
! <x> = mixt_frac * mu_x_1 + ( 1 - mixt_frac ) * mu_x_2;
!
! <x'^2> = mixt_frac * ( ( mu_x_1 - <x> )^2 + sigma_x_1^2 )
! + ( 1 - mixt_frac ) * ( ( mu_x_2 - <x> )^2 + sigma_x_2^2 );
!
! <x'^3> = mixt_frac * ( mu_x_1 - <x> )
! * ( ( mu_x_1 - <x> )^2 + 3 * sigma_x_1^2 )
! + ( 1 - mixt_frac ) * ( mu_x_2 - <x> )
! * ( ( mu_x_2 - <x> )^2 + 3 * sigma_x_2^2 );
!
! mu_x_1 - <x> = L_x_1
! * sqrt( ( 1 + Skx * sgn( <w'x'> ) / sqrt( 4 + Skx^2 ) )
! / ( 1 - Skx * sgn( <w'x'> ) / sqrt( 4 + Skx^2 ) ) )
! * sqrt( <x'^2> ) * sgn( <w'x'> ); and
!
! mu_x_2 - <x> = -L_x_2
! * sqrt( ( 1 - Skx * sgn( <w'x'> ) / sqrt( 4 + Skx^2 ) )
! / ( 1 + Skx * sgn( <w'x'> ) / sqrt( 4 + Skx^2 ) ) )
! * sqrt( <x'^2> ) * sgn( <w'x'> );
!
! where 0 <= L_x_1 <= 1, 0 <= L_x_2 <= 1, Skx is the skewness of x, such that
! Skx = <x'^3> / <x'^2>^(3/2), and sgn( <w'x'> ) is the sign of <w'x'>, such
! that:
!
! sgn( <w'x'> ) = | 1, when <w'x'> >= 0;
! | -1, when <w'x'> < 0.
!
! The resulting equations for the five PDF parameters are:
!
! mu_x_1 = <x> + L_x_1
! * sqrt( ( 1 + Skx * sgn( <w'x'> ) / sqrt( 4 + Skx^2 ) )
! / ( 1 - Skx * sgn( <w'x'> ) / sqrt( 4 + Skx^2 ) ) )
! * sqrt( <x'^2> ) * sgn( <w'x'> );
!
! mu_x_2 = <x> - L_x_2
! * sqrt( ( 1 - Skx * sgn( <w'x'> ) / sqrt( 4 + Skx^2 ) )
! / ( 1 + Skx * sgn( <w'x'> ) / sqrt( 4 + Skx^2 ) ) )
! * sqrt( <x'^2> ) * sgn( <w'x'> );
!
! mixt_frac = 1 / ( 1 + abs( mu_x_1_nrmlized / mu_x_2_nrmlized ) );
!
! sigma_x_1 = sqrt( ( 1 - mixt_frac * mu_x_1_nrmlized^2
! - ( 1 - mixt_frac ) * mu_x_2_nrmlized^2
! + ( 1 - mixt_frac )
! * ( Skx / ( 3 * mixt_frac * mu_x_1_nrmlized )
! - mu_x_1_nrmlized^2 / 3
! + mu_x_2_nrmlized^2 / 3 ) )
! * <x'^2> ); and
!
! sigma_x_2 = sqrt( ( 1 - mixt_frac * mu_x_1_nrmlized^2
! - ( 1 - mixt_frac ) * mu_x_2_nrmlized^2
! - mixt_frac
! * ( Skx / ( 3 * mixt_frac * mu_x_1_nrmlized )
! - mu_x_1_nrmlized^2 / 3
! + mu_x_2_nrmlized^2 / 3 ) )
! * <x'^2> ); where
!
! mu_x_1_nrmlized = ( mu_x_1 - <x> ) / sqrt( <x'^2> ); and
!
! mu_x_2_nrmlized = ( mu_x_2 - <x> ) / sqrt( <x'^2> ).
!
!
! Notes:
!
! This method does NOT work for all values of L_x_1 and L_x_2 (where
! 0 <= L_x_1 <= 1 and 0 <= L_x_2 <= 1). Only a subregion of this parameter
! space produces valid results.
!
! When both L_x_1 = 0 and L_x_2 = 0, mu_x_1 = mu_x_2 = <x> (which can only
! happen when Skx = 0). In this scenario, the above equations for mixt_frac,
! sigma_x_1, and sigma_x_2 are all undefined. In this special case, the
! distribution reduces to a single Gaussian, so the following values are set:
! mixt_frac = 1/2, sigma_x_1 = sqrt( <x'^2> ), and sigma_x_2 = sqrt( <x'^2> ).
!
!
! Tunable parameters:
!
! The parameter L_x_1 controls the 1st PDF component mean while L_x_2 controls
! the 2nd PDF component mean. The equations involving the tunable parameters
! L_x_1 and L_x_2 (the mu_x_1 and mu_x_2 equations) are based on the values of
! mu_x_1 and mu_x_2 when sigma_x_1 = sigma_x_2 = 0. In this scenario, the
! equation for mixture fraction reduces to:
!
! mixt_frac = (1/2) * ( 1 +/- Skx / sqrt( 4 + Skx^2 ) ).
!
! The +/- is dependent on the sign of ( mu_x_1 - <x> ) vs. ( mu_x_2 - <x> ).
! This is dependent on sgn( <w'x'> ), and the mixture fraction equation is
! written as:
!
! mixt_frac = (1/2) * ( 1 - Skx * sgn( <w'x'> ) / sqrt( 4 + Skx^2 ) ).
!
! Meanwhile, the equation for 1 - mixt_frac is:
!
! 1 - mixt_frac = (1/2) * ( 1 + Skx * sgn( <w'x'> ) / sqrt( 4 + Skx^2 ) ).
!
! When sigma_x_1 = sigma_x_2 = 0, the equations for mu_x_1 and mu_x_2 are:
!
! mu_x_1 = <x> + sqrt( ( 1 - mixt_frac ) / mixt_frac ) * sqrt( <x'^2> )
! * sgn( <w'x'> ); and
!
! mu_x_2 = <x> - sqrt( mixt_frac / ( 1 - mixt_frac ) ) * sqrt( <x'^2> )
! * sgn( <w'x'> ).
!
! Substituting the equations for mixt_frac and 1 - mixt_frac into the
! equations for mu_x_1 and mu_x_2 (when sigma_x_1 = sigma_x_2 = 0), the
! equations for mu_x_1 and mu_x_2 become:
!
! mu_x_1 = <x> + sqrt( ( 1 + Skx * sgn( <w'x'> ) / sqrt( 4 + Skx^2 ) )
! / ( 1 - Skx * sgn( <w'x'> ) / sqrt( 4 + Skx^2 ) ) )
! * sqrt( <x'^2> ) * sgn( <w'x'> ); and
!
! mu_x_2 = <x> - sqrt( ( 1 - Skx * sgn( <w'x'> ) / sqrt( 4 + Skx^2 ) )
! / ( 1 + Skx * sgn( <w'x'> ) / sqrt( 4 + Skx^2 ) ) )
! * sqrt( <x'^2> ) * sgn( <w'x'> ).
!
! These equations represent the maximum deviation of mu_x_1 and mu_x_2 from
! the overall mean, <x>. The range of parameters of L_x_i is 0 <= L_x_i <= 1.
! When L_x_1 = L_x_2 = 0, the value of mu_x_1 = mu_x_2 = <x> (and the
! distribution becomes a single Gaussian). When L_x_i = 1, the value of
! mu_x_i - <x> is at its maximum magnitude.
!
! The values of L_x_1 and L_x_2 are also calculated by skewness functions.
! Those functions are:
!
! L_x_1 = l_x_1 * abs( Skx ) / sqrt( 4 + Skx^2 ); and
! L_x_2 = l_x_2 * abs( Skx ) / sqrt( 4 + Skx^2 );
!
! where both l_x_1 and l_x_2 are tunable parameters.
!
! As previously stated, this method does not work for all combinations of
! L_x_1 and L_x_2, but rather only for a subregion of parameter space. This
! applies to l_x_1 and l_x_2, as well. The conditions on l_x_1 and l_x_2 are:
!
! 2/3 < l_x_1 < 1 and 0 < l_x_2 < 1; when Skx * sgn( <w'x'> ) >= 0; and
! 0 < l_x_1 < 1 and 2/3 < l_x_2 < 1; when Skx * sgn( <w'x'> ) < 0.
!
! The condition that l_x_1 > 2/3 prevents a negative PDF component variance
! when Skx = 0.
!
!
! Equations for PDF component standard deviations:
!
! The equations for the PDF component standard deviations can also be written
! as:
!
! sigma_x_1 = sqrt( coef_sigma_x_1_sqd * <x'^2> ); and
!
! sigma_x_2 = sqrt( coef_sigma_x_2_sqd * <x'^2> ); where
!
! coef_sigma_x_1_sqd = 1 - mixt_frac * mu_x_1_nrmlized^2
! - ( 1 - mixt_frac ) * mu_x_2_nrmlized^2
! + ( 1 - mixt_frac )
! * ( Skx / ( 3 * mixt_frac * mu_x_1_nrmlized )
! - mu_x_1_nrmlized^2 / 3
! + mu_x_2_nrmlized^2 / 3 ); and
!
! coef_sigma_x_2_sqd = 1 - mixt_frac * mu_x_1_nrmlized^2
! - ( 1 - mixt_frac ) * mu_x_2_nrmlized^2
! - mixt_frac
! * ( Skx / ( 3 * mixt_frac * mu_x_1_nrmlized )
! - mu_x_1_nrmlized^2 / 3
! + mu_x_2_nrmlized^2 / 3 ).
!
! The above equations can be substituted into an equation for a variable that
! has been derived by integrating over the PDF. Many variables like this are
! used in parts of the predictive equation set. These substitutions allow
! some terms to solved implicitly or semi-implicitly in the predictive
! equations.
!
!
!=============================================================================
subroutine calc_setter_parameters( xm, xp2, Skx, sgn_wpxp, & ! In
big_L_x_1, big_L_x_2, & ! In
mu_x_1, mu_x_2, sigma_x_1_sqd, & ! Out
sigma_x_2_sqd, mixt_frac, & ! Out
coef_sigma_x_1_sqd, & ! Out
coef_sigma_x_2_sqd ) ! Out
! Description:
! Calculates the PDF component means, the PDF component standard deviations,
! and the mixture fraction for the variable that sets the PDF.
! References:
!-----------------------------------------------------------------------
use constants_clubb, only: &
four, & ! Variable(s)
three, &
one, &
one_half, &
zero, &
eps
use clubb_precision, only: &
core_rknd ! Variable(s)
implicit none
! Input Variables
real( kind = core_rknd ), intent(in) :: &
xm, & ! Mean of x (overall) [units vary]
xp2, & ! Variance of x (overall) [(units vary)^2]
Skx, & ! Skewness of x [-]
sgn_wpxp, & ! Sign of the covariance of w and x (overall) [-]
big_L_x_1, & ! Parameter for the spread of the 1st PDF comp. mean of x [-]
big_L_x_2 ! Parameter for the spread of the 2nd PDF comp. mean of x [-]
! Output Variables
real( kind = core_rknd ), intent(out) :: &
mu_x_1, & ! Mean of x (1st PDF component) [units vary]
mu_x_2, & ! Mean of x (2nd PDF component) [units vary]
sigma_x_1_sqd, & ! Variance of x (1st PDF component) [(units vary)^2]
sigma_x_2_sqd, & ! Variance of x (2nd PDF component) [(units vary)^2]
mixt_frac ! Mixture fraction b [-]
real( kind = core_rknd ), intent(out) :: &
coef_sigma_x_1_sqd, & ! sigma_x_1^2 = coef_sigma_x_1_sqd * <x'^2> [-]
coef_sigma_x_2_sqd ! sigma_x_2^2 = coef_sigma_x_2_sqd * <x'^2> [-]
! Local Variables
real( kind = core_rknd ) :: &
mu_x_1_nrmlized, & ! Normalized mean of x (1st PDF component) [-]
mu_x_2_nrmlized ! Normalized mean of x (2nd PDF component) [-]
real( kind = core_rknd ) :: &
factor_plus, &
factor_minus, &
sqrt_factor_plus_ov_minus, &
sqrt_factor_minus_ov_plus, &
mu_x_1_nrmlized_thresh
! Calculate the factors in the PDF component mean equations.
factor_plus = one + Skx * sgn_wpxp / sqrt( four + Skx**2 )
factor_minus = one - Skx * sgn_wpxp / sqrt( four + Skx**2 )
sqrt_factor_plus_ov_minus = sqrt( factor_plus / factor_minus )
sqrt_factor_minus_ov_plus = sqrt( factor_minus / factor_plus )
! Calculate the normalized mean of x in the 1st PDF component.
mu_x_1_nrmlized = big_L_x_1 * sqrt_factor_plus_ov_minus * sgn_wpxp
! Calculate the normalized mean of x in the 2nd PDF component.
mu_x_2_nrmlized = -big_L_x_2 * sqrt_factor_minus_ov_plus * sgn_wpxp
! Calculate the mean of x in the 1st PDF component.
mu_x_1 = xm + mu_x_1_nrmlized * sqrt( xp2 )
! Calculate the mean of x in the 2nd PDF component.
mu_x_2 = xm + mu_x_2_nrmlized * sqrt( xp2 )
! Calculate the mixture fraction.
if ( abs( mu_x_1_nrmlized ) >= eps &
.and. abs( mu_x_2_nrmlized ) >= eps ) then
mixt_frac = one / ( one + abs( mu_x_1_nrmlized / mu_x_2_nrmlized ) )
elseif ( abs( mu_x_1_nrmlized ) >= eps &
.and. abs( mu_x_2_nrmlized ) < eps ) then
mixt_frac = one / ( one + abs( mu_x_1_nrmlized / eps ) )
elseif ( abs( mu_x_1_nrmlized ) < eps &
.and. abs( mu_x_2_nrmlized ) >= eps ) then
mixt_frac = one / ( one + abs( eps / mu_x_2_nrmlized ) )
else ! abs( mu_x_1_nrmlized ) < eps and abs( mu_x_2_nrmlized ) < eps
mixt_frac = one_half
endif
! Use a minimum magnitude value of mu_x_1_nrmlized in the denominator of a
! term in the PDF component variance equations in order to prevent a
! divide-by-zero error.
if ( mu_x_1_nrmlized >= zero ) then
mu_x_1_nrmlized_thresh = max( mu_x_1_nrmlized, eps )
else ! mu_x_1_nrmlized < 0
mu_x_1_nrmlized_thresh = min( mu_x_1_nrmlized, -eps )
endif ! mu_x_1_nrmlized >= 0
! Calculate the variance of x in the 1st PDF component.
coef_sigma_x_1_sqd &
= one - mixt_frac * mu_x_1_nrmlized**2 &
- ( one - mixt_frac ) * mu_x_2_nrmlized**2 &
+ ( one - mixt_frac ) &
* ( Skx / ( three * mixt_frac * mu_x_1_nrmlized_thresh ) &
- mu_x_1_nrmlized**2 / three + mu_x_2_nrmlized**2 / three )
sigma_x_1_sqd = coef_sigma_x_1_sqd * xp2
! Calculate the variance of x in the 2nd PDF component.
coef_sigma_x_2_sqd &
= one - mixt_frac * mu_x_1_nrmlized**2 &
- ( one - mixt_frac ) * mu_x_2_nrmlized**2 &
- mixt_frac &
* ( Skx / ( three * mixt_frac * mu_x_1_nrmlized_thresh ) &
- mu_x_1_nrmlized**2 / three + mu_x_2_nrmlized**2 / three )
sigma_x_2_sqd = coef_sigma_x_2_sqd * xp2
return
end subroutine calc_setter_parameters
!=============================================================================
subroutine calc_L_x_Skx_fnc( Skx, sgn_wpxp, & ! In
small_l_x_1, small_l_x_2, & ! In
big_L_x_1, big_L_x_2 ) ! Out
! Description:
! Calculates the values of big_L_x_1 and big_L_x_2 as functions of Skx.
! References:
!-----------------------------------------------------------------------
use constants_clubb, only: &
four, & ! Variable(s)
zero
use clubb_precision, only: &
core_rknd ! Variable(s)
implicit none
! Input Variables
real( kind = core_rknd ), intent(in) :: &
Skx, & ! Skewness of x (overall) [-]
sgn_wpxp, & ! Sign of the covariance of w and x (overall) [-]
small_l_x_1, & ! Param. for the spread of the 1st PDF comp. mean of x [-]
small_l_x_2 ! Param. for the spread of the 2nd PDF comp. mean of x [-]
! Output Variable
real( kind = core_rknd ), intent(out) :: &
big_L_x_1, & ! Parameter for the spread of the 1st PDF comp. mean of x [-]
big_L_x_2 ! Parameter for the spread of the 2nd PDF comp. mean of x [-]
! Local Variable
real( kind = core_rknd ) :: &
Skx_fnc_factor
! The values of L_x_1 and L_x_2 are calculated by skewness functions.
! Those functions are:
!
! L_x_1 = l_x_1 * abs( Skx ) / sqrt( 4 + Skx^2 ); and
! L_x_2 = l_x_2 * abs( Skx ) / sqrt( 4 + Skx^2 ).
!
! The conditions on l_x_1 and l_x_2 are:
!
! 2/3 < l_x_1 < 1 and 0 < l_x_2 < 1; when Skx * sgn( <w'x'> ) >= 0; and
! 0 < l_x_1 < 1 and 2/3 < l_x_2 < 1; when Skx * sgn( <w'x'> ) < 0.
!
! For simplicity, this can also be accomplished by setting 2/3 < l_x_1 < 1
! and 0 < l_x_2 < 1, and then using the following equations.
!
! When Skx * sgn( <w'x'> ) >= 0:
! L_x_1 = l_x_1 * abs( Skx ) / sqrt( 4 + Skx^2 ); and
! L_x_2 = l_x_2 * abs( Skx ) / sqrt( 4 + Skx^2 );
!
! otherwise, when Skx * sgn( <w'x'> ) < 0, switch l_x_1 and l_x_2:
! L_x_1 = l_x_2 * abs( Skx ) / sqrt( 4 + Skx^2 ); and
! L_x_2 = l_x_1 * abs( Skx ) / sqrt( 4 + Skx^2 ).
Skx_fnc_factor = abs( Skx ) / sqrt( four + Skx**2 )
if ( Skx * sgn_wpxp >= zero ) then
big_L_x_1 = small_l_x_1 * Skx_fnc_factor
big_L_x_2 = small_l_x_2 * Skx_fnc_factor
else ! Skx * sgn_wpxp < 0
big_L_x_1 = small_l_x_2 * Skx_fnc_factor
big_L_x_2 = small_l_x_1 * Skx_fnc_factor
endif
return
end subroutine calc_L_x_Skx_fnc
!=============================================================================
!
! DESCRIPTION OF THE METHOD FOR EACH RESPONDING VARIABLE
! ======================================================
!
! In order to find equations for the four PDF parameters for each responding
! variable, which are mu_x_1, mu_x_2, sigma_x_1, and sigma_x_2 (where x stands
! for a responding variable here), four equations are needed. These four
! equations are the equations for <x>, <x'^2>, and <x'^3> as found by
! integrating over the PDF. Additionally, one more equation, which involves
! tunable parameter L_x_1, and which is used to help control the mean of the
! 1st PDF component, is used in this equation set. The four equations are:
!
! <x> = mixt_frac * mu_x_1 + ( 1 - mixt_frac ) * mu_x_2;
!
! <x'^2> = mixt_frac * ( ( mu_x_1 - <x> )^2 + sigma_x_1^2 )
! + ( 1 - mixt_frac ) * ( ( mu_x_2 - <x> )^2 + sigma_x_2^2 );
!
! <x'^3> = mixt_frac * ( mu_x_1 - <x> )
! * ( ( mu_x_1 - <x> )^2 + 3 * sigma_x_1^2 )
! + ( 1 - mixt_frac ) * ( mu_x_2 - <x> )
! * ( ( mu_x_2 - <x> )^2 + 3 * sigma_x_2^2 ); and
!
! mu_x_1 - <x> = L_x_1
! * sqrt( ( 1 + Skx * sgn( <w'x'> ) / sqrt( 4 + Skx^2 ) )
! / ( 1 - Skx * sgn( <w'x'> ) / sqrt( 4 + Skx^2 ) ) )
! * sqrt( <x'^2> ) * sgn( <w'x'> );
!
! where 0 <= L_x_1 <= 1, Skx is the skewness of x, such that
! Skx = <x'^3> / <x'^2>^(3/2), and sgn( <w'x'> ) is given by:
!
! sgn( <w'x'> ) = | 1, when <w'x'> >= 0;
! | -1, when <w'x'> < 0.
!
! The resulting equations for the four PDF parameters are:
!
! mu_x_1 = <x> + L_x_1
! * sqrt( ( 1 + Skx * sgn( <w'x'> ) / sqrt( 4 + Skx^2 ) )
! / ( 1 - Skx * sgn( <w'x'> ) / sqrt( 4 + Skx^2 ) ) )
! * sqrt( <x'^2> ) * sgn( <w'x'> );
!
! mu_x_2 = <x> - ( mixt_frac / ( 1 - mixt_frac ) ) * ( mu_x_1 - <x> );
!
! sigma_x_1 = sqrt( ( 1 - mixt_frac * mu_x_1_nrmlized^2
! - ( 1 - mixt_frac ) * mu_x_2_nrmlized^2
! + ( 1 - mixt_frac )
! * ( Skx / ( 3 * mixt_frac * mu_x_1_nrmlized )
! - mu_x_1_nrmlized^2 / 3
! + mu_x_2_nrmlized^2 / 3 ) )
! * <x'^2> ); and
!
! sigma_x_2 = sqrt( ( 1 - mixt_frac * mu_x_1_nrmlized^2
! - ( 1 - mixt_frac ) * mu_x_2_nrmlized^2
! - mixt_frac
! * ( Skx / ( 3 * mixt_frac * mu_x_1_nrmlized )
! - mu_x_1_nrmlized^2 / 3
! + mu_x_2_nrmlized^2 / 3 ) )
! * <x'^2> ); where
!
! mu_x_1_nrmlized = ( mu_x_1 - <x> ) / sqrt( <x'^2> ); and
!
! mu_x_2_nrmlized = ( mu_x_2 - <x> ) / sqrt( <x'^2> ).
!
!
! Notes:
!
! When L_x_1 = 0, mu_x_1 = mu_x_2 = <x>, sigma_x_1^2 = sigma_x_2^2 = <x'^2>,
! and the distribution reduces to a single Gaussian.
!
!
! Equations for PDF component standard deviations:
!
! The equations for the PDF component standard deviations can also be written
! as:
!
! sigma_x_1 = sqrt( coef_sigma_x_1_sqd * <x'^2> ); and
!
! sigma_x_2 = sqrt( coef_sigma_x_2_sqd * <x'^2> ); where
!
! coef_sigma_x_1_sqd = 1 - mixt_frac * mu_x_1_nrmlized^2
! - ( 1 - mixt_frac ) * mu_x_2_nrmlized^2
! + ( 1 - mixt_frac )
! * ( Skx / ( 3 * mixt_frac * mu_x_1_nrmlized )
! - mu_x_1_nrmlized^2 / 3
! + mu_x_2_nrmlized^2 / 3 ); and
!
! coef_sigma_x_2_sqd = 1 - mixt_frac * mu_x_1_nrmlized^2
! - ( 1 - mixt_frac ) * mu_x_2_nrmlized^2
! - mixt_frac
! * ( Skx / ( 3 * mixt_frac * mu_x_1_nrmlized )
! - mu_x_1_nrmlized^2 / 3
! + mu_x_2_nrmlized^2 / 3 ).
!
! The above equations can be substituted into an equation for a variable that
! has been derived by integrating over the PDF. Many variables like this are
! used in parts of the predictive equation set. These substitutions allow
! some terms to solved implicitly or semi-implicitly in the predictive
! equations.
!
!
!=============================================================================
subroutine calc_respnder_parameters( xm, xp2, Skx, sgn_wpxp, & ! In
mixt_frac, big_L_x_1, & ! In
mu_x_1, mu_x_2, & ! Out
sigma_x_1_sqd, sigma_x_2_sqd, & ! Out
coef_sigma_x_1_sqd, & ! Out
coef_sigma_x_2_sqd ) ! Out
! Description:
! Calculates the PDF component means, the PDF component standard deviations,
! and the mixture fraction for the variable that sets the PDF.
! References:
!-----------------------------------------------------------------------
use constants_clubb, only: &
four, & ! Variable(s)
three, &
one, &
zero, &
eps
use clubb_precision, only: &
core_rknd ! Variable(s)
implicit none
! Input Variables
real( kind = core_rknd ), intent(in) :: &
xm, & ! Mean of x (overall) [units vary]
xp2, & ! Variance of x (overall) [(units vary)^2]
Skx, & ! Skewness of x [-]
sgn_wpxp, & ! Sign of the covariance of w and x (overall) [-]
mixt_frac, & ! Mixture fraction [-]
big_L_x_1 ! Parameter for the spread of the 1st PDF comp. mean of x [-]
! Output Variables
real( kind = core_rknd ), intent(out) :: &
mu_x_1, & ! Mean of x (1st PDF component) [units vary]
mu_x_2, & ! Mean of x (2nd PDF component) [units vary]
sigma_x_1_sqd, & ! Variance of x (1st PDF component) [(units vary)^2]
sigma_x_2_sqd ! Variance of x (2nd PDF component) [(units vary)^2]
real( kind = core_rknd ), intent(out) :: &
coef_sigma_x_1_sqd, & ! sigma_x_1^2 = coef_sigma_x_1_sqd * <x'^2> [-]
coef_sigma_x_2_sqd ! sigma_x_2^2 = coef_sigma_x_2_sqd * <x'^2> [-]
! Local Variables
real( kind = core_rknd ) :: &
mu_x_1_nrmlized, & ! Normalized mean of x (1st PDF component) [-]
mu_x_2_nrmlized ! Normalized mean of x (2nd PDF component) [-]
real( kind = core_rknd ) :: &
factor_plus, &
factor_minus, &
sqrt_factor_plus_ov_minus, &
mu_x_1_nrmlized_thresh
! Calculate the factors in the PDF component mean equations.
factor_plus = one + Skx * sgn_wpxp / sqrt( four + Skx**2 )
factor_minus = one - Skx * sgn_wpxp / sqrt( four + Skx**2 )
sqrt_factor_plus_ov_minus = sqrt( factor_plus / factor_minus )
! Calculate the normalized mean of x in the 1st PDF component.
mu_x_1_nrmlized = big_L_x_1 * sqrt_factor_plus_ov_minus * sgn_wpxp
! Calculate the normalized mean of x in the 2nd PDF component.
mu_x_2_nrmlized = - ( mixt_frac / ( one - mixt_frac ) ) * mu_x_1_nrmlized
! Calculate the mean of x in the 1st PDF component.
mu_x_1 = xm + mu_x_1_nrmlized * sqrt( xp2 )
! Calculate the mean of x in the 2nd PDF component.
mu_x_2 = xm + mu_x_2_nrmlized * sqrt( xp2 )
! Use a minimum magnitude value of mu_x_1_nrmlized in the denominator of a
! term in the PDF component variance equations in order to prevent a
! divide-by-zero error.
if ( mu_x_1_nrmlized >= zero ) then
mu_x_1_nrmlized_thresh = max( mu_x_1_nrmlized, eps )
else ! mu_x_1_nrmlized < 0
mu_x_1_nrmlized_thresh = min( mu_x_1_nrmlized, -eps )
endif ! mu_x_1_nrmlized >= 0
! Calculate the variance of x in the 1st PDF component.
coef_sigma_x_1_sqd &
= one - mixt_frac * mu_x_1_nrmlized**2 &
- ( one - mixt_frac ) * mu_x_2_nrmlized**2 &
+ ( one - mixt_frac ) &
* ( Skx / ( three * mixt_frac * mu_x_1_nrmlized_thresh ) &
- mu_x_1_nrmlized**2 / three + mu_x_2_nrmlized**2 / three )
sigma_x_1_sqd = coef_sigma_x_1_sqd * xp2
! Calculate the variance of x in the 2nd PDF component.
coef_sigma_x_2_sqd &
= one - mixt_frac * mu_x_1_nrmlized**2 &
- ( one - mixt_frac ) * mu_x_2_nrmlized**2 &
- mixt_frac &
* ( Skx / ( three * mixt_frac * mu_x_1_nrmlized_thresh ) &
- mu_x_1_nrmlized**2 / three + mu_x_2_nrmlized**2 / three )
sigma_x_2_sqd = coef_sigma_x_2_sqd * xp2
return
end subroutine calc_respnder_parameters
!=============================================================================
end module new_tsdadg_pdf