source: LMDZ6/branches/contrails/libf/obsolete/regr_lat_time_climoz_m.f90 @ 5444

Last change on this file since 5444 was 5312, checked in by abarral, 8 weeks ago

.f90 <-> .F90

  • Property copyright set to
    Name of program: LMDZ
    Creation date: 1984
    Version: LMDZ5
    License: CeCILL version 2
    Holder: Laboratoire de m\'et\'eorologie dynamique, CNRS, UMR 8539
    See the license file in the root directory
File size: 16.7 KB
Line 
1! $Id$
2module regr_lat_time_climoz_m
3
4  ! Author: Lionel GUEZ
5
6  implicit none
7
8  private
9  public regr_lat_time_climoz
10
11contains
12
13  subroutine regr_lat_time_climoz(read_climoz)
14
15    ! "regr_lat_time_climoz" stands for "regrid latitude time
16    ! climatology ozone".
17
18    ! This procedure reads a climatology of ozone from a NetCDF file,
19    ! regrids it in latitude and time, and writes the regridded field
20    ! to a new NetCDF file.
21
22    ! The input field depends on time, pressure level and latitude.
23
24    ! If the input field has missing values, they must be signaled by
25    ! the "missing_value" attribute.
26
27    ! We assume that the input field is a step function of latitude
28    ! and that the input latitude coordinate gives the centers of steps.
29    ! Regridding in latitude is made by averaging, with a cosine of
30    ! latitude factor.
31    ! The target LMDZ latitude grid is the "scalar" grid: "rlatu".
32    ! The values of "rlatu" are taken to be the centers of intervals.
33
34    ! We assume that in the input file:
35
36    ! -- Latitude is in degrees.
37
38    ! -- Latitude and pressure are strictly monotonic (as all NetCDF
39    ! coordinate variables should be).
40
41    ! -- The time coordinate is in ascending order (even though we do
42    ! not use its values).
43    ! The input file may contain either values for 12 months or values
44    ! for 14 months.
45    ! If there are 14 months then we assume that we have (in that order):
46    ! December, January, February, ..., November, December, January
47
48    ! -- Missing values are contiguous, at the bottom of
49    ! the vertical domain and at the latitudinal boundaries.
50
51    ! If values are all missing at a given latitude and date, then we
52    ! replace those missing values by values at the closest latitude,
53    ! equatorward, with valid values.
54    ! Then, at each latitude and each date, the missing values are replaced
55    ! by the lowest valid value above missing values.
56
57    ! Regridding in time is by linear interpolation.
58    ! Monthly values are processed to get daily values, on the basis
59    ! of a 360-day calendar.
60    ! If there are 14 months, we use the first December value to
61    ! interpolate values between January 1st and mid-January.
62    ! We use the last January value to interpolate values between
63    ! mid-December and end of December.
64    ! If there are only 12 months in the input file then we assume
65    ! periodicity for interpolation at the beginning and at the end of the
66    ! year.
67
68    use mod_grid_phy_lmdz, ONLY : nbp_lat
69    use regr1_conserv_m, only: regr1_conserv
70    use regr3_lint_m, only: regr3_lint
71    use netcdf95, only: handle_err, nf95_close, nf95_get_att, nf95_gw_var, &
72         nf95_inq_dimid, nf95_inq_varid, nf95_inquire_dimension, nf95_open, &
73         nf95_put_var
74    use netcdf, only: nf90_get_att, nf90_get_var, nf90_noerr, nf90_nowrite
75    use assert_m, only: assert
76    use regular_lonlat_mod, only : boundslat_reg, south
77    use nrtype, only: pi
78    use slopes_m, only: slopes
79
80    integer, intent(in):: read_climoz ! read ozone climatology
81    ! Allowed values are 1 and 2
82    ! 1: read a single ozone climatology that will be used day and night
83    ! 2: read two ozone climatologies, the average day and night
84    ! climatology and the daylight climatology
85
86    ! Variables local to the procedure:
87
88    integer n_plev ! number of pressure levels in the input data
89    integer n_lat ! number of latitudes in the input data
90    integer n_month ! number of months in the input data
91
92    real, pointer:: latitude(:)
93    ! (of input data, converted to rad, sorted in strictly ascending order)
94
95    real, allocatable:: sin_lat_in_edg(:)
96    ! (sine of edges of latitude intervals for input data, in rad, in strictly
97    ! ascending order)
98
99    real, pointer:: plev(:)
100    ! pressure levels of input data, sorted in strictly ascending
101    ! order, converted to hPa
102
103    logical desc_lat ! latitude in descending order in the input file
104    logical desc_plev ! pressure levels in descending order in the input file
105
106    real, allocatable:: o3_in(:, :, :, :)
107    ! (n_lat, n_plev, n_month, read_climoz)
108    ! ozone climatologies from the input file
109    ! "o3_in(j, k, :, :)" is at latitude "latitude(j)" and pressure
110    ! level "plev(k)".
111    ! Third dimension is month index, first value may be December or January.
112    ! "o3_in(:, :, :, 1)" is for the day- night average, "o3_in(:, :, :, 2)"
113    ! is for daylight.
114
115    real missing_value
116
117    real, allocatable:: o3_regr_lat(:, :, :, :)
118    ! (nbp_lat, n_plev, 0:13, read_climoz)
119    ! mean of "o3_in" over a latitude interval of LMDZ
120    ! First dimension is latitude interval.
121    ! The latitude interval for "o3_regr_lat(j,:, :, :)" contains "rlatu(j)".
122    ! If "j" is between 2 and "nbp_lat - 1" then the interval is:
123    ! [rlatv(j), rlatv(j-1)]
124    ! If "j" is 1 or "nbp_lat" then the interval is:
125    ! [rlatv(1), pi / 2]
126    ! or:
127    ! [- pi / 2, rlatv(nbp_lat - 1)]
128    ! respectively.
129    ! "o3_regr_lat(:, k, :, :)" is for pressure level "plev(k)".
130    ! Third dimension is month number, 1 for January.
131    ! "o3_regr_lat(:, :, :, 1)" is average day and night,
132    ! "o3_regr_lat(:, :, :, 2)" is for daylight.
133
134    real, allocatable:: o3_out(:, :, :, :)
135    ! (nbp_lat, n_plev, 360, read_climoz)
136    ! regridded ozone climatology
137    ! "o3_out(j, k, l, :)" is at latitude "rlatu(j)", pressure
138    ! level "plev(k)" and date "January 1st 0h" + "tmidday(l)", in a
139    ! 360-day calendar.
140    ! "o3_out(:, :, :, 1)" is average day and night,
141    ! "o3_out(:, :, :, 2)" is for daylight.
142
143    integer j, k, l,m
144
145    ! For NetCDF:
146    integer ncid_in, ncid_out ! IDs for input and output files
147    integer varid_plev, varid_time, varid, ncerr, dimid
148    character(len=80) press_unit ! pressure unit
149
150    integer varid_in(read_climoz), varid_out(read_climoz)
151    ! index 1 is for average ozone day and night, index 2 is for
152    ! daylight ozone.
153
154    real, parameter:: tmidmonth(0:13) = (/(-15. + 30. * l, l = 0, 13)/)
155    ! (time to middle of month, in days since January 1st 0h, in a
156    ! 360-day calendar)
157    ! (We add values -15 and 375 so that, for example, day 3 of the year is
158    ! interpolated between the December and the January value.)
159
160    real, parameter:: tmidday(360) = (/(l + 0.5, l = 0, 359)/)
161    ! (time to middle of day, in days since January 1st 0h, in a
162    ! 360-day calendar)
163
164    !---------------------------------
165
166    print *, "Call sequence information: regr_lat_time_climoz"
167    call assert(read_climoz == 1 .or. read_climoz == 2, "regr_lat_time_climoz")
168
169    call nf95_open("climoz.nc", nf90_nowrite, ncid_in)
170
171    ! Get coordinates from the input file:
172
173    call nf95_inq_varid(ncid_in, "latitude", varid)
174    call nf95_gw_var(ncid_in, varid, latitude)
175    ! Convert from degrees to rad, because we will take the sine of latitude:
176    latitude = latitude / 180. * pi
177    n_lat = size(latitude)
178    ! We need to supply the latitudes to "regr1_conserv" in
179    ! ascending order, so invert order if necessary:
180    desc_lat = latitude(1) > latitude(n_lat)
181    if (desc_lat) latitude = latitude(n_lat:1:-1)
182
183    ! Compute edges of latitude intervals:
184    allocate(sin_lat_in_edg(n_lat + 1))
185    sin_lat_in_edg(1) = - 1.
186    forall (j = 2:n_lat) sin_lat_in_edg(j) = sin((latitude(j - 1) &
187         + latitude(j)) / 2.)
188    sin_lat_in_edg(n_lat + 1) = 1.
189    deallocate(latitude) ! pointer
190
191    call nf95_inq_varid(ncid_in, "plev", varid)
192    call nf95_gw_var(ncid_in, varid, plev)
193    n_plev = size(plev)
194    ! We only need the pressure coordinate to copy it to the output file.
195    ! The program "gcm" will assume that pressure levels are in
196    ! ascending order in the regridded climatology so invert order if
197    ! necessary:
198    desc_plev = plev(1) > plev(n_plev)
199    if (desc_plev) plev = plev(n_plev:1:-1)
200    call nf95_get_att(ncid_in, varid, "units", press_unit)
201    if (press_unit == "Pa") then
202       ! Convert to hPa:
203       plev = plev / 100.
204    elseif (press_unit /= "hPa") then
205       print *, "regr_lat_time_climoz: the only recognized units are Pa " &
206            // "and hPa."
207       stop 1
208    end if
209
210    ! Create the output file and get the variable IDs:
211    call prepare_out(ncid_in, n_plev, ncid_out, varid_out, varid_plev, &
212         varid_time)
213
214    ! Write remaining coordinate variables:
215    call nf95_put_var(ncid_out, varid_plev, plev)
216    call nf95_put_var(ncid_out, varid_time, tmidday)
217
218    deallocate(plev) ! pointer
219
220    ! Get the  number of months:
221    call nf95_inq_dimid(ncid_in, "time", dimid)
222    call nf95_inquire_dimension(ncid_in, dimid, nclen=n_month)
223
224    allocate(o3_in(n_lat, n_plev, n_month, read_climoz))
225
226    call nf95_inq_varid(ncid_in, "tro3", varid_in(1))
227    ncerr = nf90_get_var(ncid_in, varid_in(1), o3_in(:, :, :, 1))
228    call handle_err("regr_lat_time_climoz nf90_get_var tro3", ncerr, ncid_in)
229
230    if (read_climoz == 2) then
231       call nf95_inq_varid(ncid_in, "tro3_daylight", varid_in(2))
232       ncerr = nf90_get_var(ncid_in, varid_in(2), o3_in(:, :, :, 2))
233       call handle_err("regr_lat_time_climoz nf90_get_var tro3_daylight", &
234            ncerr, ncid_in, varid_in(2))
235    end if
236
237    if (desc_lat) o3_in = o3_in(n_lat:1:-1, :, :, :)
238    if (desc_plev) o3_in = o3_in(:, n_plev:1:-1, :, :)
239
240    do m = 1, read_climoz
241       ncerr = nf90_get_att(ncid_in, varid_in(m), "missing_value", &
242            missing_value)
243       if (ncerr == nf90_noerr) then
244          do l = 1, n_month
245             ! Take care of latitudes where values are all missing:
246
247             ! Next to the south pole:
248             j = 1
249             do while (o3_in(j, 1, l, m) == missing_value)
250                j = j + 1
251             end do
252             if (j > 1) o3_in(:j-1, :, l, m) = &
253                  spread(o3_in(j, :, l, m), dim=1, ncopies=j-1)
254             
255             ! Next to the north pole:
256             j = n_lat
257             do while (o3_in(j, 1, l, m) == missing_value)
258                j = j - 1
259             end do
260             if (j < n_lat) o3_in(j+1:, :, l, m) = &
261                  spread(o3_in(j, :, l, m), dim=1, ncopies=n_lat-j)
262
263             ! Take care of missing values at high pressure:
264             do j = 1, n_lat
265                ! Find missing values, starting from top of atmosphere
266                ! and going down.
267                ! We have already taken care of latitudes full of
268                ! missing values so the highest level has a valid value.
269                k = 2
270                do while  (o3_in(j, k, l, m) /= missing_value .and. k < n_plev)
271                   k = k + 1
272                end do
273                ! Replace missing values with the valid value at the
274                ! lowest level above missing values:
275                if (o3_in(j, k, l, m) == missing_value) &
276                     o3_in(j, k:n_plev, l, m) = o3_in(j, k-1, l, m)
277             end do
278          end do
279       else
280          print *, "regr_lat_time_climoz: field ", m, &
281               ", no missing value attribute"
282       end if
283    end do
284
285    call nf95_close(ncid_in)
286
287    allocate(o3_regr_lat(nbp_lat, n_plev, 0:13, read_climoz))
288    allocate(o3_out(nbp_lat, n_plev, 360, read_climoz))
289
290    ! Regrid in latitude:
291    ! We average with respect to sine of latitude, which is
292    ! equivalent to weighting by cosine of latitude:
293    if (n_month == 12) then
294       print *, &
295            "Found 12 months in ozone climatologies, assuming periodicity..."
296       call regr1_conserv(o3_in, xs = sin_lat_in_edg, &
297            xt = (/- 1., sin(boundslat_reg(nbp_lat - 1:1:- 1, south)), 1./), &
298            vt = o3_regr_lat(nbp_lat:1:- 1, :, 1:12, :), &
299            slope = slopes(o3_in, sin_lat_in_edg))
300       ! (invert order of indices in "o3_regr_lat" because "rlatu" is
301       ! in descending order)
302
303       ! Duplicate January and December values, in preparation of time
304       ! interpolation:
305       o3_regr_lat(:, :, 0, :) = o3_regr_lat(:, :, 12, :)
306       o3_regr_lat(:, :, 13, :) = o3_regr_lat(:, :, 1, :)
307    else
308       print *, "Using 14 months in ozone climatologies..."
309       call regr1_conserv(o3_in, xs = sin_lat_in_edg, &
310            xt = (/- 1., sin(boundslat_reg(nbp_lat - 1:1:- 1, south)), 1./), &
311            vt = o3_regr_lat(nbp_lat:1:- 1, :, :, :), &
312            slope = slopes(o3_in, sin_lat_in_edg))
313       ! (invert order of indices in "o3_regr_lat" because "rlatu" is
314       ! in descending order)
315    end if
316
317    ! Regrid in time by linear interpolation:
318    o3_out = regr3_lint(o3_regr_lat, tmidmonth, tmidday)
319
320    ! Write to file:
321    do m = 1, read_climoz
322       call nf95_put_var(ncid_out, varid_out(m), o3_out(nbp_lat:1:-1, :, :, m))
323       ! (The order of "rlatu" is inverted in the output file)
324    end do
325
326    call nf95_close(ncid_out)
327
328  end subroutine regr_lat_time_climoz
329
330  !********************************************
331
332  subroutine prepare_out(ncid_in, n_plev, ncid_out, varid_out, varid_plev, &
333       varid_time)
334
335    ! This subroutine creates the NetCDF output file, defines
336    ! dimensions and variables, and writes one of the coordinate variables.
337
338    use mod_grid_phy_lmdz, ONLY : nbp_lat
339    use netcdf95, only: nf95_create, nf95_def_dim, nf95_def_var, &
340         nf95_put_att, nf95_enddef, nf95_copy_att, nf95_put_var
341    use netcdf, only: nf90_clobber, nf90_float, nf90_global
342    use nrtype, only: pi
343    use regular_lonlat_mod, only : lat_reg
344
345    integer, intent(in):: ncid_in, n_plev
346    integer, intent(out):: ncid_out, varid_plev, varid_time
347
348    integer, intent(out):: varid_out(:) ! dim(1 or 2)
349    ! "varid_out(1)" is for average ozone day and night,
350    ! "varid_out(2)" is for daylight ozone.
351
352    ! Variables local to the procedure:
353
354    integer ncerr
355    integer dimid_rlatu, dimid_plev, dimid_time
356    integer varid_rlatu
357
358    !---------------------------
359
360    print *, "Call sequence information: prepare_out"
361
362    call nf95_create("climoz_LMDZ.nc", nf90_clobber, ncid_out)
363
364    ! Dimensions:
365    call nf95_def_dim(ncid_out, "time", 360, dimid_time)
366    call nf95_def_dim(ncid_out, "plev", n_plev, dimid_plev)
367    call nf95_def_dim(ncid_out, "rlatu", nbp_lat, dimid_rlatu)
368
369    ! Define coordinate variables:
370
371    call nf95_def_var(ncid_out, "time", nf90_float, dimid_time, varid_time)
372    call nf95_put_att(ncid_out, varid_time, "units", "days since 2000-1-1")
373    call nf95_put_att(ncid_out, varid_time, "calendar", "360_day")
374    call nf95_put_att(ncid_out, varid_time, "standard_name", "time")
375
376    call nf95_def_var(ncid_out, "plev", nf90_float, dimid_plev, varid_plev)
377    call nf95_put_att(ncid_out, varid_plev, "units", "millibar")
378    call nf95_put_att(ncid_out, varid_plev, "standard_name", "air_pressure")
379    call nf95_put_att(ncid_out, varid_plev, "long_name", "air pressure")
380
381    call nf95_def_var(ncid_out, "rlatu", nf90_float, dimid_rlatu, varid_rlatu)
382    call nf95_put_att(ncid_out, varid_rlatu, "units", "degrees_north")
383    call nf95_put_att(ncid_out, varid_rlatu, "standard_name", "latitude")
384
385    ! Define the primary variables:
386
387    call nf95_def_var(ncid_out, "tro3", nf90_float, &
388         (/dimid_rlatu, dimid_plev, dimid_time/), varid_out(1))
389    call nf95_put_att(ncid_out, varid_out(1), "long_name", &
390         "ozone mole fraction")
391    call nf95_put_att(ncid_out, varid_out(1), "standard_name", &
392         "mole_fraction_of_ozone_in_air")
393
394    if (size(varid_out) == 2) then
395       call nf95_def_var(ncid_out, "tro3_daylight", nf90_float, &
396            (/dimid_rlatu, dimid_plev, dimid_time/), varid_out(2))
397       call nf95_put_att(ncid_out, varid_out(2), "long_name", &
398            "ozone mole fraction in daylight")
399    end if
400
401    ! Global attributes:
402
403    ! The following commands, copying attributes, may fail.
404    ! That is OK.
405    ! It should just mean that the attribute is not defined in the input file.
406
407    call nf95_copy_att(ncid_in, nf90_global, "Conventions", ncid_out, &
408         nf90_global, ncerr)
409    call handle_err_copy_att("Conventions")
410
411    call nf95_copy_att(ncid_in, nf90_global, "title", ncid_out, nf90_global, &
412         ncerr)
413    call handle_err_copy_att("title")
414
415    call nf95_copy_att(ncid_in, nf90_global, "institution", ncid_out, &
416         nf90_global, ncerr)
417    call handle_err_copy_att("institution")
418
419    call nf95_copy_att(ncid_in, nf90_global, "source", ncid_out, nf90_global, &
420         ncerr)
421    call handle_err_copy_att("source")
422
423    call nf95_put_att(ncid_out, nf90_global, "comment", "Regridded for LMDZ")
424
425    call nf95_enddef(ncid_out)
426
427    ! Write one of the coordinate variables:
428    call nf95_put_var(ncid_out, varid_rlatu, lat_reg(nbp_lat:1:-1) / pi * 180.)
429    ! (convert from rad to degrees and sort in ascending order)
430
431  contains
432
433    subroutine handle_err_copy_att(att_name)
434
435      use netcdf, only: nf90_noerr, nf90_strerror
436
437      character(len=*), intent(in):: att_name
438
439      !----------------------------------------
440
441      if (ncerr /= nf90_noerr) then
442         print *, "regr_lat_time_climoz_m prepare_out nf95_copy_att " &
443              // att_name // " -- " // trim(nf90_strerror(ncerr))
444      end if
445
446    end subroutine handle_err_copy_att
447
448  end subroutine prepare_out
449
450end module regr_lat_time_climoz_m
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