python转换wrf输出的数据为网页可视化json格式

begin
  a = addfile("/Users/WRF/outdata/2022071000/wrfout_d01_2022-07-10_01:00:00","r")
  lat2d = a->XLAT(0,:,:)
  lon2d = a->XLONG(0,:,:)
  lat1d = lat2d(:,0)
  lon1d = lon2d(0,:)
 
  time = wrf_user_getvar(a,"XTIME",-1)
  u10 = wrf_user_getvar(a,"U10",0)
  v10 = wrf_user_getvar(a,"V10",0)
  slp = wrf_user_getvar(a,"slp",0)
  t2  = wrf_user_getvar(a,"T2",0)
  td  = wrf_user_getvar(a,"td",0)
  rainc = wrf_user_getvar(a,"RAINC",0)
  rainnc = wrf_user_getvar(a,"RAINNC",0)
  
  u10@lat2d = lat2d
  u10@lon2d = lon2d
  u10_ip = rcm2rgrid_Wrap(lat2d,lon2d,u10,lat1d,lon1d,0)
  
  v10@lat2d = lat2d
  v10@lon2d = lon2d
  v10_ip = rcm2rgrid_Wrap(lat2d,lon2d,v10,lat1d,lon1d,0)
  
  slp_ip  =   rcm2rgrid_Wrap(lat2d,lon2d,slp,lat1d,lon1d,0)
  t2_ip  =   rcm2rgrid_Wrap(lat2d,lon2d,t2,lat1d,lon1d,0)
  td_ip  =   rcm2rgrid_Wrap(lat2d,lon2d,td,lat1d,lon1d,0)
  rainc_ip  =   rcm2rgrid_Wrap(lat2d,lon2d,rainc,lat1d,lon1d,0)
  rainnc_ip  =   rcm2rgrid_Wrap(lat2d,lon2d,rainnc,lat1d,lon1d,0)
  outf = addfile("/Users/wrfout_d01_2022-07-10_01:00:00.nc","c")
  outf->time =  time
  outf->lat  =  lat2d
  outf->lon  =  lon2d
  outf->u10  =  u10_ip
  outf->v10  =  v10_ip
  outf->slp  =  slp_ip
  outf->t2   =  t2_ip
  outf->td   =  td_ip
  outf->rainc   =  rainc_ip
  outf->rainnc  =  rainnc_ip
end

load "$NCARG_ROOT/lib/ncarg/nclscripts/esmf/ESMF_regridding.ncl"

begin
  a = addfile("/Users/WRF/outdata/2022071000/wrfout_d01_2022-07-10_01:00:00","r")
  u10 = wrf_user_getvar(a,"U10",0)
  v10 = wrf_user_getvar(a,"V10",0)
  slp = wrf_user_getvar(a,"slp",0)
  t2  = wrf_user_getvar(a,"T2",0)
;  td  = wrf_user_getvar(a,"td",0)
  rainc = wrf_user_getvar(a,"RAINC",0)
  rainnc = wrf_user_getvar(a,"RAINNC",0)
  
  u10@lat2d = a->XLAT(0,:,:) 
  u10@lon2d = a->XLONG(0,:,:)
  v10@lat2d = a->XLAT(0,:,:) 
  v10@lon2d = a->XLONG(0,:,:)
  slp@lat2d = a->XLAT(0,:,:) 
  slp@lon2d = a->XLONG(0,:,:)
  t2@lat2d = a->XLAT(0,:,:) 
  t2@lon2d = a->XLONG(0,:,:)
;  td@lat2d = a->XLAT(0,:,:) 
;  td@lon2d = a->XLONG(0,:,:)
  rainc@lat2d = a->XLAT(0,:,:) 
  rainc@lon2d = a->XLONG(0,:,:)
  rainnc@lat2d = a->XLAT(0,:,:) 
  rainnc@lon2d = a->XLONG(0,:,:)
  
  lat2d = a->XLAT(0,:,:)
  lon2d = a->XLONG(0,:,:)
  lat1d = lat2d(:,0)
  lon1d = lon2d(0,:)
  latS = -20
  latN = 50
  lonW = 95
  lonE = 145

  Opt = True
  Opt@InterpMethod = "bilinear" 
  Opt@ForceOverwrite = True 
  
  Opt@SrcMask2D = where(.not. ismissing(v10),1,0) 
  Opt@DstGridType = "0.1deg"
  Opt@DstLLCorner = (/latS, lonW /) 
  Opt@DstURCorner = (/latN, lonE /) 
  
  u10_regrid = ESMF_regrid(u10,Opt)
  v10_regrid = ESMF_regrid(v10,Opt)
  slp_regrid = ESMF_regrid(slp,Opt)
  t2_regrid = ESMF_regrid(t2,Opt)
;  td_regrid = ESMF_regrid(td,Opt)
  rainc_regrid = ESMF_regrid(rainc,Opt)
  rainnc_regrid = ESMF_regrid(rainnc,Opt)
  
  time = wrf_user_getvar(a,"XTIME",-1)
  
  nlon = dimsizes(v10_regrid&lon)
  nlat = dimsizes(v10_regrid&lat)
  
  ofile = "wrfout_d01_2022-07-10_01:00:00.nc"
  system("rm -rf "+ofile) 
  fout = addfile(ofile,"c") 
  
  dimNames = (/"lat", "lon"/)
  dimSizes = (/nlat, nlon/)
  dimUnlim = (/False, False/)
  
  filedimdef(fout,dimNames,dimSizes,dimUnlim) ;-- define dimensions
  
  filevardef(fout,"lat",typeof(v10_regrid&lat),getvardims(v10_regrid&lat))
  filevardef(fout,"lon",typeof(v10_regrid&lon),getvardims(v10_regrid&lon))
  
  filevardef(fout,"u10",typeof(u10_regrid),getvardims(u10_regrid))
  filevardef(fout,"v10",typeof(v10_regrid),getvardims(v10_regrid))
  filevardef(fout,"slp",typeof(slp_regrid),getvardims(slp_regrid))
  filevardef(fout,"t2",typeof(t2_regrid),getvardims(t2_regrid))
;  filevardef(fout,"td",typeof(td_regrid),getvardims(td_regrid))
  filevardef(fout,"rainc",typeof(rainc_regrid),getvardims(rainc_regrid))
  filevardef(fout,"rainnc",typeof(rainnc_regrid),getvardims(rainnc_regrid))
    
  filevarattdef(fout,"lat",v10_regrid&lat) ;-- copy lat attributes
  filevarattdef(fout,"lon",v10_regrid&lon) ;-- copy lon attributes
  filevarattdef(fout,"u10",u10_regrid)
  filevarattdef(fout,"v10",v10_regrid)
  filevarattdef(fout,"slp",slp_regrid)
  filevarattdef(fout,"t2",t2_regrid)
;  filevarattdef(fout,"td",td_regrid)
  filevarattdef(fout,"rainc",rainc_regrid)
  filevarattdef(fout,"rainnc",rainnc_regrid)
  
  setfileoption(fout,"DefineMode",False)

  fout->u10 = (/u10_regrid/)
  fout->v10 = (/v10_regrid/) 
  fout->slp = (/slp_regrid/) 
  fout->t2 = (/t2_regrid/) 
;  fout->td = (/td_regrid/) 
  fout->rainc  = (/rainc_regrid/) 
  fout->rainnc = (/rainnc_regrid/) 
  
  fout->lat = (/v10_regrid&lat/) ;-- write lat to new netCDF file
  fout->lon = (/v10_regrid&lon/) ;-- write lon to new netCDF file
  fout->time =  time
end

# -*- coding: utf-8 -*-
"""
Created on %(date)s

@author: %(jixianpu)s

Email : 211311040008@hhu.edu.cn

introduction : keep learning althongh walk slowly
"""
"""
用来读取用ncl插值后的wrfoutput.nc 数据,并生成对应文件名的json格式
"""
import pandas as pd
import os
import json
import netCDF4 as nc
import numpy as np
import  datetime
from netCDF4 import Dataset
import argparse
from argparse import RawDescriptionHelpFORMatter
import xarray as xr
import sys
import glob

date = sys.argv[1]
date = str(date)
frst = sys.argv[2]
step = sys.argv[3]

path = r'/Users/WRF/outdata/2022071000/'#只能是已经存在的文件目录且有数据才可以进行读取
start = datetime.datetime.strptime(date,'%Y%m%d%H').strftime("%Y-%m-%d_%H:%M:%S")
end = (datetime.datetime.strptime(date,'%Y%m%d%H')+datetime.timedelta(hours=int(frst))).strftime("%Y-%m-%d_%H:%M:%S")
intp = (datetime.datetime.strptime(date,'%Y%m%d%H')+datetime.timedelta(hours=int(step))).strftime("%Y-%m-%d_%H:%M:%S")
fstart = path+'/wrfout_d01_'+start+'*'
fintp  = path+'/wrfout_d01_'+intp+'*'
fend   = path+'/wrfout_d01_'+end+'*'
file = path+'/*'
filestart = glob.glob(fstart)
fileintp  = glob.glob(fintp)
fileend   = glob.glob(fend)
filelist  = glob.glob(file)
filelist.sort()   
rstart = np.array(np.where(np.array(filelist)==filestart))[0][0]
rintp = np.array(np.where(np.array(filelist)==fileintp))[0][0]
rend   = np.array(np.where(np.array(filelist)==fileend))[0][0]
fn = filelist[rstart:rend:rintp]
outroot = 'Users/'    
for i in fn:
    uhdr = {"header":{"discipline":0,"disciplineName":"Meteorological products","gribEdition":2,"gribLength":131858,"center":0,"centerName":"WRF OUTPUT","subcenter":0,"refTime":"2014-01-31T00:00:00.000Z","significanceOfRT":1,"significanceOfRTName":"Start of forecast","productStatus":0,"productStatusName":"Operational products","productType":1,"productTypeName":"Forecast products","productDefinitionTemplate":0,"productDefinitionTemplateName":"Analysis/forecast at horizontal level/layer at a point in time","parameterCateGory":2,"parameterCategoryName":"Momentum","parameterNumber":2,"parameterNumberName":"U-component_of_wind","parameterUnit":"m.s-1","genProcessType":2,"genProcessTypeName":"Forecast","forecastTime":3,"surface1Type":103,"surface1TypeName":"Specified height level above ground","surface1Value":10,"surface2Type":255,"surface2TypeName":"Missing","surface2Value":0,"gridDefinitionTemplate":0,"gridDefinitionTemplateName":"Latitude_Longitude","numberPoints":65160,"shape":6,"shapeName":"Earth spherical with radius of 6,371,229.0 m","gridUnits":"degrees","resolution":48,"winds":"true","scanMode":0,"nx":360,"ny":181,"basicAngle":0,"subDivisions":0,"lo1":0,"la1":90,"lo2":359,"la2":-90,"dx":1,"dy":1}}

    vhdr = {"header":{"discipline":0,"disciplineName":"Meteorological products","gribEdition":2,"gribLength":131858,"center":0,"centerName":"WRF OUTPUT","subcenter":0,"refTime":"2014-01-31T00:00:00.000Z","significanceOfRT":1,"significanceOfRTName":"Start of forecast","productStatus":0,"productStatusName":"Operational products","productType":1,"productTypeName":"Forecast products","productDefinitionTemplate":0,"productDefinitionTemplateName":"Analysis/forecast at horizontal level/layer at a point in time","parameterCategory":2,"parameterCategoryName":"Momentum","parameterNumber":3,"parameterNumberName":"V-component_of_wind","parameterUnit":"m.s-1","genProcessType":2,"genProcessTypeName":"Forecast","forecastTime":3,"surface1Type":103,"surface1TypeName":"Specified height level above ground","surface1Value":10,"surface2Type":255,"surface2TypeName":"Missing","surface2Value":0,"gridDefinitionTemplate":0,"gridDefinitionTemplateName":"Latitude_Longitude","numberPoints":65160,"shape":6,"shapeName":"Earth spherical with radius of 6,371,229.0 m","gridUnits":"degrees","resolution":48,"winds":"true","scanMode":0,"nx":360,"ny":181,"basicAngle":0,"subDivisions":0,"lo1":0,"la1":90,"lo2":359,"la2":-90,"dx":1,"dy":1}}

    data = [uhdr, vhdr]
    newf = Dataset(i)
    lat = np.array(newf.variables['lat'])
    # print(fn,lat)
    lon = np.array(newf.variables['lon'])
    dys = np.diff(lat, axis = 0).mean(1)
    dy = float(dys.mean())
    dxs = np.diff(lon, axis = 1).mean(0)
    dx = float(dxs.mean())
    nx = float(lon.shape[1])
    ny = float(lat.shape[0])
    la1 = float(lat[-1, -1])
    la2 = float(lat[0, 0])
    lo1 = float(lon[0, 0])
    lo2 = float(lon[-1, -1])

    time =(newf.variables['time'])

    dates = nc.num2date(time[:],units=time.units)

    dt = pd.to_datetime(np.array(dates, dtype='datetime64[s]')).strftime("%Y%m%d%H%M%S")

    tms =pd.to_datetime(np.array(dates, dtype='datetime64[s]')).strftime("%Y-%m-%d_%H:%M:%S")
    for ti, time in enumerate(dt):

        datestr = (dt[0][:8])
        timestr = (dt[0][8:10])+'00'

        dirpath = outroot + date
        os.makedirs(dirpath, exist_ok = True)
        outpath = os.path.join(dirpath, '%s.json' % (i[-19:]))
        for u0_or_v1 in [0, 1]:

            h = data[u0_or_v1]['header']
            h['la1'] = la1
            h['la2'] = la2
            h['lo1'] = lo1
            h['lo2'] = lo2
            h['nx'] = nx
            h['ny'] = ny
            h['dx'] = dx
            h['dy'] = dy
            h['forecastTime'] = 0
            h['refTime'] = tms[0] + '.000Z'

            h['gribLength'] = 1538 + nx * ny * 2
            if u0_or_v1 == 0:
                data[u0_or_v1]['data'] = np.array(newf.variables['u10']).ravel().tolist()
            elif u0_or_v1 == 1:
                data[u0_or_v1]['data'] = np.array(newf.variables['v10']).ravel().tolist()
        if ti == 0:
            outf = open(outpath, 'w')
            json.dump(data, outf)
            outf.close()
        outf = open(outpath, 'w')
        json.dump(data, outf)
        outf.close()

python  convert_to_json.py 2022071000 12 06

# -*- coding: utf-8 -*-
"""
Created on %(date)s

@author: %(jixianpu)s

Email : 211311040008@hhu.edu.cn

introduction : keep learning althongh walk slowly
"""
from __future__ import print_function, unicode_literals
import pandas as pd
import os
import json
import netCDF4 as nc
import numpy as np
import  datetime
from netCDF4 import Dataset
import argparse
from argparse import RawDescriptionHelpFormatter
import xarray as xr
# parser = argparse.ArgumentParser(description = """
# """, formatter_class = RawDescriptionHelpFormatter)

args = r'J:/wrf自动化/wrfout_d01_2022-07-10_01_00_00.nc'

outroot = r'D:/'

uhdr = {"header":{
                  "nx":360,
                  "ny":181,
                  "max":11,
                  }}

data = [uhdr]
newf = Dataset(args)
lat = np.array(newf.variables['lat'])
lon = np.array(newf.variables['lon'])
u10 = np.array(newf.variables['u10'])
v10 = np.array(newf.variables['v10'])

# indx = u10>1000

# u10[indx] = np.nan
# v10[indx] = np.nan

w10 = np.nanmax(np.sqrt(u10*u10+v10*v10))

dys = np.diff(lat, axis = 0).mean(1)
dy =    float(dys.mean())
print('Latitude Error:', np.abs((dy / dys) - 1).max())
print('Latitude Sum Error:', (dy / dys - 1).sum())
dxs = np.diff(lon, axis = 1).mean(0)
dx =    float(dxs.mean())
print('Longitude Error:', np.abs(dx / dxs - 1).max())
print('Longitude Sum Error:', (dx / dxs - 1).sum())

nx =    float(lon.shape[1])
ny =    float(lat.shape[0])

la1 =    float(lat[-1, -1])
la2 =   float(lat[0, 0])
lo1 =   float(lon[0, 0])
lo2 =   float(lon[-1, -1])
time =(newf.variables['time'])
dates = nc.num2date(time[:],units=time.units)
dt = pd.to_datetime(np.array(dates, dtype='datetime64[s]')).strftime("%Y%m%d%H%M%S")

ds= {
                      "nx":360,
                      "ny":181,
                      "max":11,
                      # "lo1":0,
                      # "la1":90,
                      # "lo2":359,
                      # "la2":-90,
                      # "dx":1,
                      # "dy":1,
                      # "parameterUnit":"m.s-1",
                      'data':{}
        }

ds['max']   =    float(w10)
ds['nx']    =    (nx)
ds['ny']    =    (ny)
for ti, time in enumerate(dt):
    #2012/02/07/0100Z/wind/surface/level/orthographic=-74.01,4.38,29184
    datestr = (dt[0][:8])
    timestr = (dt[0][8:10])+'00'
    print('Add "#' + datestr + '/' + timestr + 'Z/wind/surface/level/orthographic" to url to see this time')
    dirpath = os.path.join('D:', *datestr.split('/'))
    os.makedirs(dirpath, exist_ok = True)
    outpath = os.path.join(dirpath, '%s-wind-surface-level-gfs-1.0.json' % (timestr,))
    udata=u10.ravel()
    data[0]['data']=[]
    for i in range(len(udata)):

        data[0]['data'].append([
        u10.ravel().tolist()[i],
        v10.ravel().tolist()[i]])

    ds['data'] = data[0]['data']

outf = open(outpath, 'w')
json.dump(ds,outf)
outf.close()