source: LMDZ6/trunk/libf/phylmd/ecrad.v1.5.1/radiation_cloud.F90 @ 5450

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1! radiation_cloud.F90 - Derived type to store cloud/precip properties
2!
3! (C) Copyright 2014- ECMWF.
4!
5! This software is licensed under the terms of the Apache Licence Version 2.0
6! which can be obtained at http://www.apache.org/licenses/LICENSE-2.0.
7!
8! In applying this licence, ECMWF does not waive the privileges and immunities
9! granted to it by virtue of its status as an intergovernmental organisation
10! nor does it submit to any jurisdiction.
11!
12! Author:  Robin Hogan
13! Email:   r.j.hogan@ecmwf.int
14!
15! Modifications
16!   2019-01-14  R. Hogan  Added inv_inhom_effective_size variable
17!   2019-01-14  R. Hogan  Added out_of_physical_bounds routine
18!   2019-06-14  R. Hogan  Added capability to store any number of cloud/precip types
19
20module radiation_cloud
21
22  use parkind1, only : jprb
23
24  implicit none
25  public
26
27  !---------------------------------------------------------------------
28  ! The intention is that all variables describing clouds and
29  ! radiatively-active precipitation are contained in this derived
30  ! type, and if cloud variables are to be added in future, they can
31  ! be added to this type without requiring extra variables to be
32  ! passed between subroutines elsewhere in the program.
33  type cloud_type
34    ! For maximum flexibility, an arbitrary number "ntype" of
35    ! hydrometeor types can be stored, dimensioned (ncol,nlev,ntype)
36    integer                                   :: ntype = 0
37    real(jprb), allocatable, dimension(:,:,:) :: &
38         &  mixing_ratio, &  ! mass mixing ratio (kg/kg)
39         &  effective_radius ! (m)
40
41    ! For backwards compatibility, we also allow for the two
42    ! traditional cloud types, liquid cloud droplets and ice cloud
43    ! particles, dimensioned (ncol,nlev)
44    real(jprb), pointer, dimension(:,:) :: &
45         &  q_liq,  q_ice,  & ! mass mixing ratio (kg/kg)
46         &  re_liq, re_ice    ! effective radius (m)
47
48    ! For the moment, the different types of hydrometeor are assumed
49    ! to be mixed with each other, so there is just one cloud fraction
50    ! variable varying from 0 to 1
51    real(jprb), allocatable, dimension(:,:) :: fraction
52
53    ! The fractional standard deviation of cloud optical depth in the
54    ! cloudy part of the gridbox.  In the Tripleclouds representation
55    ! of cloud inhomogeneity, this is implemented by splitting the
56    ! cloudy part of the gridbox into two equal-area regions, one
57    ! with the cloud optical depth scaled by 1+fractional_std and the
58    ! other scaled by 1-fractional_std. This variable is dimensioned
59    ! (ncol,nlev)
60    real(jprb), allocatable, dimension(:,:) :: fractional_std
61
62    ! The inverse of the effective horizontal size of the clouds in
63    ! the gridbox, used to compute the cloud edge length per unit
64    ! gridbox area for use in representing 3D effects. This variable
65    ! is dimensioned (ncol,nlev).
66    real(jprb), allocatable, dimension(:,:) :: inv_cloud_effective_size ! m-1
67
68    ! Similarly for the in-cloud heterogeneities, used to compute the
69    ! edge length between the optically thin and thick cloudy regions
70    ! of the gridbox.
71    real(jprb), allocatable, dimension(:,:) :: inv_inhom_effective_size ! m-1
72
73    ! The following variable describes the overlap of cloud boundaries
74    ! in adjacent layers, with dimensions (ncol,nlev-1): 1 corresponds
75    ! to maximum overlap and 0 to random overlap. Depending on the
76    ! ecRad configuration, it may be the "alpha" overlap parameter of
77    ! Hogan and Illingworth (2000) or the "beta" overlap parameter of
78    ! Shonk et al. (2010).
79    real(jprb), allocatable, dimension(:,:) :: overlap_param
80
81  contains
82    procedure :: allocate   => allocate_cloud_arrays
83    procedure :: deallocate => deallocate_cloud_arrays
84    procedure :: set_overlap_param
85    procedure :: set_overlap_param_approx
86    procedure :: create_fractional_std
87    procedure :: create_inv_cloud_effective_size
88    procedure :: create_inv_cloud_effective_size_eta
89    procedure :: param_cloud_effective_separation_eta
90    procedure :: crop_cloud_fraction
91    procedure :: out_of_physical_bounds
92
93  end type cloud_type
94
95contains
96
97  !---------------------------------------------------------------------
98  ! Allocate arrays for describing clouds and precipitation, although
99  ! in the offline code these are allocated when they are read from
100  ! the NetCDF file
101  subroutine allocate_cloud_arrays(this, ncol, nlev, ntype, use_inhom_effective_size)
102
103    use yomhook,     only : lhook, dr_hook
104
105    class(cloud_type), intent(inout), target :: this
106    integer, intent(in)              :: ncol   ! Number of columns
107    integer, intent(in)              :: nlev   ! Number of levels
108    ! Number of cloud/precip particle types.  If not present then the
109    ! older cloud behaviour is assumed: two types are present, (1)
110    ! liquid and (2) ice, and they can be accessed via q_liq, q_ice,
111    ! re_liq and re_ice.
112    integer, intent(in), optional    :: ntype
113    logical, intent(in), optional    :: use_inhom_effective_size
114
115    real(jprb)                       :: hook_handle
116
117    if (lhook) call dr_hook('radiation_cloud:allocate',0,hook_handle)
118
119    if (present(ntype)) then
120      this%ntype = ntype
121    else
122      this%ntype = 2
123    end if
124    allocate(this%mixing_ratio(ncol,nlev,this%ntype))
125    allocate(this%effective_radius(ncol,nlev,this%ntype))
126    nullify(this%q_liq)
127    nullify(this%q_ice)
128    nullify(this%re_liq)
129    nullify(this%re_ice)
130    if (.not. present(ntype)) then
131      ! Older interface in which only liquid and ice are supported
132      this%q_liq  => this%mixing_ratio(:,:,1)
133      this%q_ice  => this%mixing_ratio(:,:,2)
134      this%re_liq => this%effective_radius(:,:,1)
135      this%re_ice => this%effective_radius(:,:,2)
136    end if
137
138    allocate(this%fraction(ncol,nlev))
139    allocate(this%overlap_param(ncol,nlev-1))
140    allocate(this%fractional_std(ncol,nlev))
141    allocate(this%inv_cloud_effective_size(ncol,nlev))
142
143    if (present(use_inhom_effective_size)) then
144      if (use_inhom_effective_size) then
145        allocate(this%inv_inhom_effective_size(ncol,nlev))
146      end if
147    end if
148
149    if (lhook) call dr_hook('radiation_cloud:allocate',1,hook_handle)
150
151  end subroutine allocate_cloud_arrays
152
153
154  !---------------------------------------------------------------------
155  ! Deallocate arrays
156  subroutine deallocate_cloud_arrays(this)
157
158    use yomhook,     only : lhook, dr_hook
159
160    class(cloud_type), intent(inout) :: this
161
162    real(jprb)                       :: hook_handle
163
164    if (lhook) call dr_hook('radiation_cloud:deallocate',0,hook_handle)
165
166    nullify(this%q_liq)
167    nullify(this%q_ice)
168    nullify(this%re_liq)
169    nullify(this%re_ice)
170
171    if (allocated(this%mixing_ratio))     deallocate(this%mixing_ratio)
172    if (allocated(this%effective_radius)) deallocate(this%effective_radius)
173    if (allocated(this%fraction))         deallocate(this%fraction)
174    if (allocated(this%overlap_param))    deallocate(this%overlap_param)
175    if (allocated(this%fractional_std))   deallocate(this%fractional_std)
176    if (allocated(this%inv_cloud_effective_size)) &
177         &  deallocate(this%inv_cloud_effective_size)
178    if (allocated(this%inv_inhom_effective_size)) &
179         &  deallocate(this%inv_inhom_effective_size)
180
181    if (lhook) call dr_hook('radiation_cloud:deallocate',1,hook_handle)
182
183  end subroutine deallocate_cloud_arrays
184
185
186  !---------------------------------------------------------------------
187  ! Compute and store the overlap parameter from the provided overlap
188  ! decorrelation length (in metres).  If istartcol and/or iendcol are
189  ! provided then only columns in this range are computed.  If the
190  ! overlap_param array has not been allocated then it will be
191  ! allocated to be of the correct size relative to the pressure
192  ! field.
193  subroutine set_overlap_param(this, thermodynamics, decorrelation_length, &
194       &  istartcol, iendcol)
195
196    use yomhook,                  only : lhook, dr_hook
197    use radiation_thermodynamics, only : thermodynamics_type
198    use radiation_constants,      only : GasConstantDryAir, AccelDueToGravity
199
200    class(cloud_type),         intent(inout) :: this
201    type(thermodynamics_type), intent(in)    :: thermodynamics
202    real(jprb),                intent(in)    :: decorrelation_length ! m
203    integer,         optional, intent(in)    :: istartcol, iendcol
204
205    ! Ratio of gas constant for dry air to acceleration due to gravity
206    real(jprb), parameter :: R_over_g = GasConstantDryAir / AccelDueToGravity
207
208    ! Process only columns i1 to i2, which will be istartcol to
209    ! iendcol if they were provided
210    integer :: i1, i2
211
212    integer :: ncol, nlev
213
214    integer :: jcol, jlev
215
216    real(jprb)        :: hook_handle
217
218    if (lhook) call dr_hook('radiation_cloud:set_overlap_param',0,hook_handle)
219
220    ! Pressure at half-levels, pressure_hl, is defined at nlev+1
221    ! points
222    ncol = size(thermodynamics%pressure_hl,dim=1)
223    nlev = size(thermodynamics%pressure_hl,dim=2)-1
224
225    if (present(istartcol)) then
226      i1 = istartcol
227    else
228      i1 = 1
229    end if
230
231    if (present(iendcol)) then
232      i2 = iendcol
233    else
234      i2 = ncol
235    end if
236
237    if (.not. allocated(this%overlap_param)) then
238      ! If pressure is of size (ncol,nlev+1) then overlap_param is of
239      ! size (ncol,nlev-1), since overlap parameter is only defined here
240      ! for interfaces between model layers, not for the interface to
241      ! space or the surface
242      allocate(this%overlap_param(ncol, nlev-1))
243    end if
244
245    if (thermodynamics%pressure_hl(i1,2) > thermodynamics%pressure_hl(i1,1)) then
246      ! Pressure is increasing with index (order of layers is
247      ! top-of-atmosphere to surface). In case pressure_hl(:,1)=0, we
248      ! don't take the logarithm of the first pressure in each column.
249      do jcol = i1,i2
250        this%overlap_param(jcol,1) = exp(-(R_over_g/decorrelation_length) &
251             &                            * thermodynamics%temperature_hl(jcol,2) &
252             &                            *log(thermodynamics%pressure_hl(jcol,3) &
253             &                                /thermodynamics%pressure_hl(jcol,2)))
254      end do
255
256      do jlev = 2,nlev-1
257        do jcol = i1,i2
258          this%overlap_param(jcol,jlev) = exp(-(0.5_jprb*R_over_g/decorrelation_length) &
259              &                            * thermodynamics%temperature_hl(jcol,jlev+1) &
260              &                            *log(thermodynamics%pressure_hl(jcol,jlev+2) &
261              &                                /thermodynamics%pressure_hl(jcol,jlev)))
262        end do
263      end do
264
265    else
266       ! Pressure is decreasing with index (order of layers is surface
267       ! to top-of-atmosphere).  In case pressure_hl(:,nlev+1)=0, we
268       ! don't take the logarithm of the last pressure in each column.
269      do jlev = 1,nlev-2
270        do jcol = i1,i2
271          this%overlap_param(jcol,jlev) = exp(-(0.5_jprb*R_over_g/decorrelation_length) &
272              &                            * thermodynamics%temperature_hl(jcol,jlev+1) &
273              &                            *log(thermodynamics%pressure_hl(jcol,jlev) &
274              &                                /thermodynamics%pressure_hl(jcol,jlev+2)))
275        end do
276      end do
277
278      do jcol = i1,i2
279        this%overlap_param(jcol,nlev-1) = exp(-(R_over_g/decorrelation_length) &
280            &                            * thermodynamics%temperature_hl(jcol,nlev) &
281            &                            *log(thermodynamics%pressure_hl(jcol,nlev-1) &
282            &                                /thermodynamics%pressure_hl(jcol,nlev)))
283      end do
284    end if
285
286    if (lhook) call dr_hook('radiation_cloud:set_overlap_param',1,hook_handle)
287
288  end subroutine set_overlap_param
289
290
291  !---------------------------------------------------------------------
292  ! Compute and store the overlap parameter from the provided overlap
293  ! decorrelation length (in metres).  If istartcol and/or iendcol are
294  ! provided then only columns in this range are computed.  If the
295  ! overlap_param array has not been allocated then it will be
296  ! allocated to be of the correct size relative to the pressure
297  ! field. This is the APPROXIMATE method as it assumes a fixed
298  ! atmospheric scale height, which leads to differences particularly
299  ! in low cloud.
300  subroutine set_overlap_param_approx(this, thermodynamics, decorrelation_length, &
301       &  istartcol, iendcol)
302
303    use yomhook,                  only : lhook, dr_hook
304    use radiation_thermodynamics, only : thermodynamics_type
305
306    class(cloud_type),         intent(inout) :: this
307    type(thermodynamics_type), intent(in)    :: thermodynamics
308    real(jprb),                intent(in)    :: decorrelation_length ! m
309    integer,         optional, intent(in)    :: istartcol, iendcol
310
311    ! To convert decorrelation length (m) to overlap parameter between
312    ! layers, we need an estimate for the thickness of the layer. This
313    ! is found using the pressure difference between the edges of the
314    ! layer, along with the approximate scale height of the atmosphere
315    ! (m) given here:
316    real(jprb), parameter :: scale_height = 8000.0_jprb
317
318    ! Process only columns i1 to i2, which will be istartcol to
319    ! iendcol if they were provided
320    integer :: i1, i2
321
322    integer :: ncol, nlev
323
324    real(jprb)        :: hook_handle
325
326    if (lhook) call dr_hook('radiation_cloud:set_overlap_param_approx',0,hook_handle)
327
328    ! Pressure at half-levels, pressure_hl, is defined at nlev+1
329    ! points
330    ncol = size(thermodynamics%pressure_hl,dim=1)
331    nlev = size(thermodynamics%pressure_hl,dim=2)-1
332
333    if (present(istartcol)) then
334      i1 = istartcol
335    else
336      i1 = 1
337    end if
338
339    if (present(iendcol)) then
340      i2 = iendcol
341    else
342      i2 = ncol
343    end if
344
345    if (.not. allocated(this%overlap_param)) then
346      ! If pressure is of size (ncol,nlev+1) then overlap_param is of
347      ! size (ncol,nlev-1), since overlap parameter is only defined here
348      ! for interfaces between model layers, not for the interface to
349      ! space or the surface
350      allocate(this%overlap_param(ncol, nlev-1))
351    end if
352
353    if (thermodynamics%pressure_hl(i1,2) > thermodynamics%pressure_hl(i1,1)) then
354       ! Pressure is increasing with index (order of layers is
355       ! top-of-atmosphere to surface). In case pressure_hl(:,1)=0, we
356       ! don't take the logarithm of the first pressure in each
357       ! column.
358       this%overlap_param(i1:i2,:) = exp(-(scale_height/decorrelation_length) &
359            &  * ( log(thermodynamics%pressure_hl(i1:i2,3:nlev+1) &
360            &         /thermodynamics%pressure_hl(i1:i2,2:nlev  )) ) )
361    else
362       ! Pressure is decreasing with index (order of layers is surface
363       ! to top-of-atmosphere).  In case pressure_hl(:,nlev+1)=0, we
364       ! don't take the logarithm of the last pressure in each column.
365       this%overlap_param(i1:i2,:) = exp(-(scale_height/decorrelation_length) &
366            &  * ( log(thermodynamics%pressure_hl(i1:i2,1:nlev-1) &
367            &         /thermodynamics%pressure_hl(i1:i2,2:nlev  )) ) )
368    end if
369
370    if (lhook) call dr_hook('radiation_cloud:set_overlap_param_approx',1,hook_handle)
371
372  end subroutine set_overlap_param_approx
373
374
375  !---------------------------------------------------------------------
376  ! Create a matrix of constant fractional standard deviations
377  ! (dimensionless)
378  subroutine create_fractional_std(this, ncol, nlev, frac_std)
379
380    use yomhook,                  only : lhook, dr_hook
381
382    class(cloud_type), intent(inout) :: this
383    integer,           intent(in)    :: ncol, nlev
384    real(jprb),        intent(in)    :: frac_std
385
386    real(jprb)             :: hook_handle
387
388    if (lhook) call dr_hook('radiation_cloud:create_fractional_std',0,hook_handle)
389
390    if (allocated(this%fractional_std)) then
391       deallocate(this%fractional_std)
392    end if
393   
394    allocate(this%fractional_std(ncol, nlev))
395
396    this%fractional_std = frac_std
397
398    if (lhook) call dr_hook('radiation_cloud:create_fractional_std',1,hook_handle)
399
400  end subroutine create_fractional_std
401
402
403  !---------------------------------------------------------------------
404  ! Create a matrix of constant inverse cloud effective size (m-1)
405  subroutine create_inv_cloud_effective_size(this, ncol, nlev, inv_eff_size)
406
407    use yomhook,                  only : lhook, dr_hook
408
409    class(cloud_type), intent(inout) :: this
410    integer,           intent(in)    :: ncol, nlev
411    real(jprb),        intent(in)    :: inv_eff_size
412
413    real(jprb)             :: hook_handle
414
415    if (lhook) call dr_hook('radiation_cloud:create_inv_cloud_effective_size',0,hook_handle)
416
417    if (allocated(this%inv_cloud_effective_size)) then
418       deallocate(this%inv_cloud_effective_size)
419    end if
420   
421    allocate(this%inv_cloud_effective_size(ncol, nlev))
422
423    this%inv_cloud_effective_size = inv_eff_size
424
425    if (lhook) call dr_hook('radiation_cloud:create_inv_cloud_effective_size',1,hook_handle)
426
427  end subroutine create_inv_cloud_effective_size
428
429
430  !---------------------------------------------------------------------
431  ! Create a matrix of inverse cloud effective size (m-1) according to
432  ! the value of eta (=pressure divided by surface pressure)
433  subroutine create_inv_cloud_effective_size_eta(this, ncol, nlev, &
434       &  pressure_hl, inv_eff_size_low, inv_eff_size_mid, inv_eff_size_high, &
435       &  eta_low_mid, eta_mid_high, istartcol, iendcol)
436
437    use yomhook,                  only : lhook, dr_hook
438
439    class(cloud_type), intent(inout) :: this
440    integer,           intent(in)    :: ncol, nlev
441    ! Pressure on half levels (Pa)
442    real(jprb),        intent(in)    :: pressure_hl(:,:)
443    ! Inverse effective size for low, mid and high cloud (m-1)
444    real(jprb),        intent(in)    :: inv_eff_size_low
445    real(jprb),        intent(in)    :: inv_eff_size_mid
446    real(jprb),        intent(in)    :: inv_eff_size_high
447    ! Eta values at low-mid and mid-high interfaces
448    real(jprb),        intent(in)    :: eta_low_mid, eta_mid_high
449    integer, optional, intent(in)    :: istartcol, iendcol
450
451    ! Ratio of layer midpoint pressure to surface pressure
452    real(jprb) :: eta(nlev)
453
454    ! Indices of column, level and surface half-level
455    integer :: jcol, isurf
456
457    ! Local values of istartcol, iendcol
458    integer :: i1, i2
459
460    real(jprb)             :: hook_handle
461
462    if (lhook) call dr_hook('radiation_cloud:create_inv_cloud_effective_size_eta',0,hook_handle)
463
464    if (allocated(this%inv_cloud_effective_size)) then
465      deallocate(this%inv_cloud_effective_size)
466    end if
467   
468    allocate(this%inv_cloud_effective_size(ncol, nlev))
469
470    if (present(istartcol)) then
471      i1 = istartcol
472    else
473      i1 = 1
474    end if
475
476    if (present(iendcol)) then
477      i2 = iendcol
478    else
479      i2 = ncol
480    end if
481
482    ! Locate the surface half-level
483    if (pressure_hl(1,1) > pressure_hl(1,2)) then
484      isurf = 1
485    else
486      isurf = nlev+1
487    end if
488
489    do jcol = i1,i2
490      eta = (pressure_hl(jcol,1:nlev)+pressure_hl(jcol,2:nlev+1)) &
491           &  * (0.5_jprb / pressure_hl(jcol,isurf))
492      where (eta > eta_low_mid)
493        this%inv_cloud_effective_size(jcol,:) = inv_eff_size_low
494      elsewhere (eta > eta_mid_high)
495        this%inv_cloud_effective_size(jcol,:) = inv_eff_size_mid
496      elsewhere
497        this%inv_cloud_effective_size(jcol,:) = inv_eff_size_high
498      end where
499    end do
500
501    if (lhook) call dr_hook('radiation_cloud:create_inv_cloud_effective_size_eta',1,hook_handle)
502
503  end subroutine create_inv_cloud_effective_size_eta
504
505
506  !---------------------------------------------------------------------
507  ! Create a matrix of inverse cloud and inhomogeneity effective size
508  ! (m-1) parameterized according to the value of eta (=pressure
509  ! divided by surface pressure): effective_separation =
510  ! coeff_a + coeff_b*exp(-(eta**power)). 
511  subroutine param_cloud_effective_separation_eta(this, ncol, nlev, &
512       &  pressure_hl, separation_surf, separation_toa, power, &
513       &  inhom_separation_factor, istartcol, iendcol)
514
515    use yomhook,                  only : lhook, dr_hook
516
517    class(cloud_type), intent(inout) :: this
518    integer,           intent(in)    :: ncol, nlev
519    ! Pressure on half levels (Pa)
520    real(jprb),        intent(in)    :: pressure_hl(:,:)
521    ! Separation distances at surface and top-of-atmosphere, and power
522    ! on eta
523    real(jprb),           intent(in) :: separation_surf ! m
524    real(jprb),           intent(in) :: separation_toa ! m
525    real(jprb),           intent(in) :: power
526    real(jprb), optional, intent(in) :: inhom_separation_factor
527    integer,    optional, intent(in) :: istartcol, iendcol
528
529    ! Ratio of layer midpoint pressure to surface pressure
530    real(jprb) :: eta(nlev)
531
532    ! Effective cloud separation (m)
533    real(jprb) :: eff_separation(nlev)
534
535    ! Coefficients used to compute effective separation distance
536    real(jprb) :: coeff_e, coeff_a, coeff_b, inhom_sep_factor
537
538    ! Indices of column, level and surface half-level
539    integer :: jcol, isurf
540
541    ! Local values of istartcol, iendcol
542    integer :: i1, i2
543
544    real(jprb) :: hook_handle
545
546    if (lhook) call dr_hook('radiation_cloud:param_cloud_effective_separation_eta',0,hook_handle)
547
548    if (present(inhom_separation_factor)) then
549      inhom_sep_factor = inhom_separation_factor
550    else
551      inhom_sep_factor = 1.0_jprb
552    end if
553
554    coeff_e = 1.0_jprb - exp(-1.0_jprb)
555    coeff_b = (separation_toa - separation_surf) / coeff_e
556    coeff_a = separation_toa - coeff_b
557
558    if (allocated(this%inv_cloud_effective_size)) then
559      deallocate(this%inv_cloud_effective_size)
560    end if
561     if (allocated(this%inv_inhom_effective_size)) then
562      deallocate(this%inv_inhom_effective_size)
563    end if
564   
565    allocate(this%inv_cloud_effective_size(ncol, nlev))
566    allocate(this%inv_inhom_effective_size(ncol, nlev))
567
568    if (present(istartcol)) then
569      i1 = istartcol
570    else
571      i1 = 1
572    end if
573
574    if (present(iendcol)) then
575      i2 = iendcol
576    else
577      i2 = ncol
578    end if
579
580    ! Locate the surface half-level
581    if (pressure_hl(1,1) > pressure_hl(1,2)) then
582      isurf = 1
583    else
584      isurf = nlev+1
585    end if
586
587    do jcol = i1,i2
588      eta = (pressure_hl(jcol,1:nlev)+pressure_hl(jcol,2:nlev+1)) &
589           &  * (0.5_jprb / pressure_hl(jcol,isurf))
590      eff_separation = coeff_a + coeff_b * exp(-eta**power)
591      this%inv_cloud_effective_size(jcol,:) = 1.0_jprb / (eff_separation &
592           &  * sqrt(max(1.0e-5_jprb,this%fraction(jcol,:)*(1.0_jprb-this%fraction(jcol,:)))))
593      this%inv_inhom_effective_size(jcol,:) = 1.0_jprb / (eff_separation * inhom_sep_factor &
594           &  * sqrt(max(1.0e-5_jprb,0.5_jprb*this%fraction(jcol,:)*(1.0_jprb-0.5_jprb*this%fraction(jcol,:)))))
595    end do
596
597    if (lhook) call dr_hook('radiation_cloud:param_cloud_effective_separation_eta',1,hook_handle)
598
599  end subroutine param_cloud_effective_separation_eta
600
601
602  !---------------------------------------------------------------------
603  ! Remove "ghost" clouds: those with a cloud fraction that is too
604  ! small to treat sensibly (e.g. because it implies that the
605  ! "in-cloud" water content is too high), or with a cloud water
606  ! content that is too small.  We do this in one place to ensure that
607  ! all subsequent subroutines can assume that if cloud_fraction > 0.0
608  ! then cloud is really present and should be treated.
609  subroutine crop_cloud_fraction(this, istartcol, iendcol, &
610       &    cloud_fraction_threshold, cloud_mixing_ratio_threshold)
611   
612    use yomhook, only : lhook, dr_hook
613
614    class(cloud_type), intent(inout) :: this
615    integer,           intent(in)    :: istartcol, iendcol
616
617    integer :: nlev, ntype
618    integer :: jcol, jlev, jh
619
620    real(jprb) :: cloud_fraction_threshold, cloud_mixing_ratio_threshold
621    real(jprb) :: sum_mixing_ratio(istartcol:iendcol)
622
623    real(jprb) :: hook_handle
624
625    if (lhook) call dr_hook('radiation_cloud:crop_cloud_fraction',0,hook_handle)
626
627    nlev  = size(this%fraction,2)
628    ntype = size(this%mixing_ratio,3)
629   
630    do jlev = 1,nlev
631      do jcol = istartcol,iendcol
632        sum_mixing_ratio(jcol) = 0.0_jprb
633      end do
634      do jh = 1, ntype
635        do jcol = istartcol,iendcol
636          sum_mixing_ratio(jcol) = sum_mixing_ratio(jcol) + this%mixing_ratio(jcol,jlev,jh)
637        end do
638      end do
639      do jcol = istartcol,iendcol
640        if (this%fraction(jcol,jlev)        < cloud_fraction_threshold &
641             &  .or. sum_mixing_ratio(jcol) < cloud_mixing_ratio_threshold) then
642          this%fraction(jcol,jlev) = 0.0_jprb
643        end if
644      end do
645    end do
646
647    if (lhook) call dr_hook('radiation_cloud:crop_cloud_fraction',1,hook_handle)
648
649  end subroutine crop_cloud_fraction
650
651
652  !---------------------------------------------------------------------
653  ! Return .true. if variables are out of a physically sensible range,
654  ! optionally only considering columns between istartcol and iendcol
655  function out_of_physical_bounds(this, istartcol, iendcol, do_fix) result(is_bad)
656
657    use yomhook,          only : lhook, dr_hook
658    use radiation_check, only : out_of_bounds_2d, out_of_bounds_3d
659
660    class(cloud_type), intent(inout) :: this
661    integer,  optional,intent(in) :: istartcol, iendcol
662    logical,  optional,intent(in) :: do_fix
663    logical                       :: is_bad
664
665    logical    :: do_fix_local
666
667    real(jprb) :: hook_handle
668
669    if (lhook) call dr_hook('radiation_cloud:out_of_physical_bounds',0,hook_handle)
670
671    if (present(do_fix)) then
672      do_fix_local = do_fix
673    else
674      do_fix_local = .false.
675    end if
676
677    is_bad =    out_of_bounds_3d(this%mixing_ratio, 'cloud%mixing_ratio', 0.0_jprb, 1.0_jprb, &
678         &                       do_fix_local, i1=istartcol, i2=iendcol) &
679         & .or. out_of_bounds_3d(this%effective_radius, 'cloud%effective_radius', 0.0_jprb, 0.1_jprb, &
680         &                       do_fix_local, i1=istartcol, i2=iendcol) &
681         & .or. out_of_bounds_2d(this%fraction, 'cloud%fraction', 0.0_jprb, 1.0_jprb, &
682         &                       do_fix_local, i1=istartcol, i2=iendcol) &
683         & .or. out_of_bounds_2d(this%fractional_std, 'fractional_std', 0.0_jprb, 10.0_jprb, &
684         &                       do_fix_local, i1=istartcol, i2=iendcol) &
685         & .or. out_of_bounds_2d(this%inv_cloud_effective_size, 'inv_cloud_effective_size', &
686         &                       0.0_jprb, 1.0_jprb, do_fix_local, i1=istartcol, i2=iendcol) &
687         & .or. out_of_bounds_2d(this%inv_inhom_effective_size, 'inv_inhom_effective_size', &
688         &                       0.0_jprb, 1.0_jprb, do_fix_local, i1=istartcol, i2=iendcol) &
689         & .or. out_of_bounds_2d(this%overlap_param, 'overlap_param', -0.5_jprb, 1.0_jprb, &
690         &                       do_fix_local, i1=istartcol, i2=iendcol)
691
692    if (lhook) call dr_hook('radiation_cloud:out_of_physical_bounds',1,hook_handle)
693
694  end function out_of_physical_bounds
695 
696end module radiation_cloud
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