Mercurial > repos > ecology > copernicusmarine
comparison divandfull.jl @ 0:4de886e6300d draft
planemo upload for repository https://github.com/galaxyecology/tools-ecology/tree/master/tools/ocean commit a7e53c429cf93485aba692b928defe6ee01633d6
author | ecology |
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date | Tue, 22 Oct 2024 15:55:13 +0000 |
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1 #Julia script | |
2 | |
3 ############################### | |
4 ## DIVAndrun analsysis ## | |
5 ############################### | |
6 import Pkg; | |
7 using Pkg | |
8 Pkg.status() | |
9 | |
10 ### Import packages | |
11 using DIVAnd | |
12 using Dates | |
13 using Printf | |
14 # Getting the arguments from the command line | |
15 args = ARGS | |
16 | |
17 # Import data | |
18 if length(args) < 4 | |
19 error("This tool needs at least 4 arguments") | |
20 else | |
21 netcdf_data = args[1] | |
22 longmin = parse(Float64, args[2]) | |
23 longmax = parse(Float64, args[3]) | |
24 latmin = parse(Float64, args[4]) | |
25 latmax = parse(Float64, args[5]) | |
26 startdate = args[6] # yyyy,mm,dd | |
27 enddate = args[7] | |
28 varname = args[8] | |
29 selmin = parse(Float64, args[9]) | |
30 selmax = parse(Float64, args[10]) | |
31 bathname = args[11] | |
32 end | |
33 | |
34 ## This script will create a climatology: | |
35 # 1. ODV data reading. | |
36 # 2. Extraction of bathymetry and creation of mask | |
37 # 3. Data download from other sources and duplicate removal. | |
38 # 4. Quality control. | |
39 # 5. Parameter optimisation. | |
40 # 6. Spatio-temporal interpolation with DIVAnd. | |
41 | |
42 | |
43 ### Configuration | |
44 # Define the horizontal, vertical (depth levels) and temporal resolutions. | |
45 # Select the variable of interest | |
46 | |
47 dx, dy = 0.125, 0.125 | |
48 lonr = longmin:dx:longmax | |
49 latr = latmin:dy:latmax | |
50 | |
51 # Convert string in date | |
52 startdate = Date(startdate, "yyyy-mm-dd") | |
53 | |
54 # extract year month day | |
55 startyear = year(startdate) | |
56 startmonth = month(startdate) | |
57 startday = day(startdate) | |
58 | |
59 # Convert string in date | |
60 enddate = Date(enddate, "yyyy-mm-dd") | |
61 | |
62 # extract year month day | |
63 endyear = year(enddate) | |
64 endmonth = month(enddate) | |
65 endday = day(enddate) | |
66 | |
67 timerange = [Date(startyear, startmonth, startday),Date(endyear, endmonth, endday)]; | |
68 | |
69 depthr = [0.,5., 10., 15., 20., 25., 30., 40., 50., 66, | |
70 75, 85, 100, 112, 125, 135, 150, 175, 200, 225, 250, | |
71 275, 300, 350, 400, 450, 500, 550, 600, 650, 700, 750, | |
72 800, 850, 900, 950, 1000, 1050, 1100, 1150, 1200, 1250, | |
73 1300, 1350, 1400, 1450, 1500, 1600, 1750, 1850, 2000]; | |
74 depthr = [0.,10.,20.]; | |
75 | |
76 varname = varname | |
77 yearlist = [1900:2023]; | |
78 monthlist = [[1,2,3],[4,5,6],[7,8,9],[10,11,12]]; | |
79 | |
80 # We create here the variable TS (for "tDataset(netcdf_data,"r")ime selector"), which allows us to work with the observations corresponding to each period of interest. | |
81 | |
82 TS = DIVAnd.TimeSelectorYearListMonthList(yearlist,monthlist); | |
83 @show TS; | |
84 | |
85 figdir = "outputs/" | |
86 if ~(isdir(figdir)) | |
87 mkdir(figdir) | |
88 else | |
89 @info("Figure directory already exists") | |
90 end | |
91 ### 1. Read your ODV file | |
92 # Adapt the datadir and datafile values. | |
93 # The example is based on a sub-setting of the Mediterranean Sea aggregated dataset. | |
94 # The dataset has been extracted around the Adriatic Sea and exported to a netCDF using Ocean Data | |
95 datadir = "../data" | |
96 | |
97 datafile = netcdf_data | |
98 | |
99 # Then you can read the full file: | |
100 @time obsval,obslon,obslat,obsdepth,obstime,obsid = NCODV.load(Float64, datafile, | |
101 "Water body $(varname)"); | |
102 | |
103 # Check the extremal values of the observations | |
104 checkobs((obslon,obslat,obsdepth,obstime),obsval,obsid) | |
105 | |
106 ### 2. Extract the bathymetry | |
107 | |
108 # It is used to delimit the domain where the interpolation is performed. | |
109 ## 2.1 Choice of bathymetry | |
110 | |
111 # Modify bathname according to the resolution required. | |
112 | |
113 @time bx,by,b = load_bath(bathname,true,lonr,latr); | |
114 | |
115 ## 2.2 Create mask | |
116 # False for sea | |
117 # True for land | |
118 | |
119 mask = falses(size(b,1),size(b,2),length(depthr)) | |
120 for k = 1:length(depthr) | |
121 for j = 1:size(b,2) | |
122 for i = 1:size(b,1) | |
123 mask[i,j,k] = b[i,j] >= depthr[k] | |
124 end | |
125 end | |
126 end | |
127 @show size(mask) | |
128 | |
129 ### 3. Quality control | |
130 # We check the salinity value. | |
131 # Adapt the criteria to your region and variable. | |
132 | |
133 sel = (obsval .<= selmax) .& (obsval .>= selmin); | |
134 | |
135 obsval = obsval[sel] | |
136 obslon = obslon[sel] | |
137 obslat = obslat[sel] | |
138 obsdepth = obsdepth[sel] | |
139 obstime = obstime[sel] | |
140 obsid = obsid[sel]; | |
141 | |
142 ### 4. Analysis parameters | |
143 # Correlation lengths and noise-to-signal ratio | |
144 | |
145 # We will use the function diva3D for the calculations. | |
146 # With this function, the correlation length has to be defined in meters, not in degrees. | |
147 | |
148 sz = (length(lonr),length(latr),length(depthr)); | |
149 lenx = fill(100_000.,sz) # 100 km | |
150 leny = fill(100_000.,sz) # 100 km | |
151 lenz = fill(25.,sz); # 25 m | |
152 len = (lenx, leny, lenz); | |
153 epsilon2 = 0.1; | |
154 | |
155 ### Output file name | |
156 outputdir = "outputs_netcdf/" | |
157 if !isdir(outputdir) | |
158 mkpath(outputdir) | |
159 end | |
160 filename = joinpath(outputdir, "Water_body_$(replace(varname," "=>"_")).nc") | |
161 | |
162 ### 7. Analysis | |
163 # Remove the result file before running the analysis, otherwise you'll get the message | |
164 if isfile(filename) | |
165 rm(filename) # delete the previous analysis | |
166 @info "Removing file $filename" | |
167 end | |
168 | |
169 ## 7.1 Plotting function | |
170 # Define a plotting function that will be applied for each time index and depth level. | |
171 # All the figures will be saved in a selected directory. | |
172 | |
173 function plotres(timeindex,sel,fit,erri) | |
174 tmp = copy(fit) | |
175 nx,ny,nz = size(tmp) | |
176 for i in 1:nz | |
177 figure("Additional-Data") | |
178 ax = subplot(1,1,1) | |
179 ax.tick_params("both",labelsize=6) | |
180 ylim(39.0, 46.0); | |
181 xlim(11.5, 20.0); | |
182 title("Depth: (timeindex)", fontsize=6) | |
183 pcolor(lonr.-dx/2.,latr.-dy/2, permutedims(tmp[:,:,i], [2,1]); | |
184 vmin = 33, vmax = 40) | |
185 colorbar(extend="both", orientation="vertical", shrink=0.8).ax.tick_params(labelsize=8) | |
186 | |
187 contourf(bx,by,permutedims(b,[2,1]), levels = [-1e5,0],colors = [[.5,.5,.5]]) | |
188 aspectratio = 1/cos(mean(latr) * pi/180) | |
189 gca().set_aspect(aspectratio) | |
190 | |
191 figname = varname * @sprintf("_%02d",i) * @sprintf("_%03d.png",timeindex) | |
192 plt.savefig(joinpath(figdir, figname), dpi=600, bbox_inches="tight"); | |
193 plt.close_figs() | |
194 end | |
195 end | |
196 | |
197 ## 7.2 Create the gridded fields using diva3d | |
198 # Here only the noise-to-signal ratio is estimated. | |
199 # Set fitcorrlen to true to also optimise the correlation length. | |
200 @time dbinfo = DIVAnd.diva3d((lonr,latr,depthr,TS), | |
201 (obslon,obslat,obsdepth,obstime), obsval, | |
202 len, epsilon2, | |
203 filename,varname, | |
204 bathname=bathname, | |
205 fitcorrlen = false, | |
206 niter_e = 2, | |
207 surfextend = true | |
208 ); | |
209 | |
210 # Save the observation metadata in the NetCDF file. | |
211 DIVAnd.saveobs(filename,(obslon,obslat,obsdepth,obstime),obsid); |