datasource.py 10.57 KiB
import datetime, os
from datetime import timezone
import glob
import numpy as np
from aeolus.geos_nav import GEOSNavigation
from util.util import GenericException
class AMVFiles:
def __init__(self, files_path, file_time_span, pattern, band='14', elem_name=None, line_name=None, lat_name=None,
lon_name=None, params=None, out_params=None, meta_dict=None, qc_params=None):
self.flist = glob.glob(files_path + pattern)
if len(self.flist) == 0:
raise GenericException('no matching files found in: ' + files_path)
self.band = band
self.ftimes = []
self.span_seconds = datetime.timedelta(minutes=file_time_span).seconds
for pname in self.flist:
dto = self.get_datetime(pname)
dto_start = dto
dto_end = dto + datetime.timedelta(minutes=file_time_span)
self.ftimes.append((dto_start.timestamp(), dto_end.timestamp()))
self.ftimes = np.array(self.ftimes)
self.flist = np.array(self.flist)
sidxs = np.argsort(self.ftimes[:, 0])
self.ftimes = self.ftimes[sidxs, :]
self.flist = self.flist[sidxs]
self.elem_name = elem_name
self.line_name = line_name
self.lon_name = lon_name
self.lat_name = lat_name
self.params = params
self.out_params = params
if out_params is not None:
self.out_params = out_params
self.meta_dict = meta_dict
self.qc_params = qc_params
def get_datetime(self, pathname):
pass
def get_navigation(self):
pass
def get_file_containing_time(self, timestamp):
k = -1
for i in range(len(self.ftimes.shape[0])):
if (timestamp >= self.ftimes[i, 0]) and (timestamp < self.ftimes[i, 1]):
k = i
break
if k < 0:
return None, None, None
return self.flist[k], self.ftimes[k, 0], k
def get_file(self, timestamp):
diff = self.ftimes[:, 0] - timestamp
midx = np.argmin(np.abs(diff))
if np.abs(self.ftimes[midx, 0] - timestamp) < self.span_seconds:
return self.flist[midx], self.ftimes[midx, 0], midx
else:
return None, None, None
def get_parameters(self):
return self.params
def get_out_parameters(self):
return self.out_params
def get_meta_dict(self):
return self.meta_dict
def get_qc_params(self):
return self.qc_params
def filter(self, qc_param):
pass
class Framework(AMVFiles):
def __init__(self, files_path, file_time_span, band='14'):
elem_name = 'Element'
line_name = 'Line'
lon_name = 'Longitude'
lat_name = 'Latitude'
#params = ['MedianPress', 'Wind_Speed', 'Wind_Dir', 'BestFitPresLvl']
params = ['MedianPress', 'Wind_Speed', 'Wind_Dir']
#out_params = ['Lon', 'Lat', 'Element', 'Line', 'pressure', 'wind_speed', 'wind_direction', 'BestFitPresLvl']
out_params = ['Lon', 'Lat', 'Element', 'Line', 'pressure', 'wind_speed', 'wind_direction']
meta_dict = {'Lon': ('degrees east', 'f4'), 'Lat': ('degrees north', 'f4'), 'Element': (None, 'i4'),
'Line': (None, 'i4'), 'pressure': ('hPa', 'f4'), 'wind_speed': ('m s-1', 'f4'),
#'wind_direction': ('degrees', 'f4'), 'BestFitPresLvl': ('hPa', 'f4')}
'wind_direction': ('degrees', 'f4')}
qc_param = 'QI'
super().__init__(files_path, file_time_span, '*WINDS_AMV_EN-'+band+'*.nc', band=band, elem_name=elem_name, params=params,
line_name=line_name, lat_name=lat_name, lon_name=lon_name, out_params=out_params, meta_dict=meta_dict, qc_params=qc_param)
def get_navigation(self):
return GEOSNavigation(sub_lon=-75.0)
def get_datetime(self, pathname):
fname = os.path.split(pathname)[1]
toks = fname.split('_')
dstr = toks[4]
tstr = toks[5]
dtstr = dstr + tstr
dto = datetime.datetime.strptime(dtstr, '%Y%j%H%M').replace(tzinfo=timezone.utc)
return dto
def filter(self, qc_param):
good = qc_param > 50
return good
class FrameworkCloudHeight(AMVFiles):
def __init__(self, files_path, file_time_span):
elem_name = 'Element'
line_name = 'Line'
lon_name = 'Longitude'
lat_name = 'Latitude'
out_params = ['CldTopPres', 'CldTopHght', 'CldOptDpth']
params = ['CldTopPres', 'CldTopHght', 'CldOptDpth']
meta_dict = {'CldTopPres': ('hPa', 'f4'), 'CldTopHght': ('km', 'f4'), 'CldOptDpth': ('km', 'f4')}
super().__init__(files_path, file_time_span, '*_CLOUD_HEIGHT_EN'+'*.nc', band=None, elem_name=elem_name, params=params,
line_name=line_name, lat_name=lat_name, lon_name=lon_name, out_params=out_params, meta_dict=meta_dict)
def get_navigation(self):
return GEOSNavigation(sub_lon=-75.0)
def get_datetime(self, pathname):
fname = os.path.split(pathname)[1]
toks = fname.split('_')
dstr = toks[4]
tstr = toks[5]
dtstr = dstr + tstr
dto = datetime.datetime.strptime(dtstr, '%Y%j%H%M').replace(tzinfo=timezone.utc)
return dto
class FrameworkCloudPhase(AMVFiles):
def __init__(self, files_path, file_time_span):
elem_name = 'Element'
line_name = 'Line'
lon_name = 'Longitude'
lat_name = 'Latitude'
out_params = ['CloudPhase', 'CloudType']
params = ['CloudPhase', 'CloudType']
meta_dict = {'CloudPhase': (None, 'i1'), 'CloudType': (None, 'i1')}
super().__init__(files_path, file_time_span, '*_CLOUD_PHASE_EN'+'*.nc', band=None, elem_name=elem_name, params=params,
line_name=line_name, lat_name=lat_name, lon_name=lon_name, out_params=out_params, meta_dict=meta_dict)
def get_navigation(self):
return GEOSNavigation(sub_lon=-75.0)
def get_datetime(self, pathname):
fname = os.path.split(pathname)[1]
toks = fname.split('_')
dstr = toks[4]
tstr = toks[5]
dtstr = dstr + tstr
dto = datetime.datetime.strptime(dtstr, '%Y%j%H%M').replace(tzinfo=timezone.utc)
return dto
class OpsCloudPhase(AMVFiles):
def __init__(self, files_path, file_time_span):
elem_name = None
line_name = None
lon_name = None
lat_name = None
out_params = ['Phase']
params = ['Phase']
meta_dict = {'Phase': (None, 'i1')}
super().__init__(files_path, file_time_span, 'OR_ABI-L2-ACTPF'+'*.nc', band=None, elem_name=elem_name, params=params,
line_name=line_name, lat_name=lat_name, lon_name=lon_name, out_params=out_params, meta_dict=meta_dict)
def get_navigation(self):
return GEOSNavigation(sub_lon=-75.0)
def get_datetime(self, pathname):
fname = os.path.split(pathname)[1]
toks = fname.split('_')
dtstr = toks[3]
dtstr = dtstr[:-3]
dto = datetime.datetime.strptime(dtstr, 's%Y%j%H%M').replace(tzinfo=timezone.utc)
return dto
class OPS(AMVFiles):
def __init__(self, files_path, file_time_span, band='14'):
elem_name = None
line_name = None
lon_name = 'lon'
lat_name = 'lat'
out_params = ['Lon', 'Lat', 'Element', 'Line', 'pressure', 'wind_speed', 'wind_direction']
params = ['pressure', 'wind_speed', 'wind_direction']
meta_dict = {'Lon': ('degrees east', 'f4'), 'Lat': ('degrees north', 'f4'), 'Element': (None, 'i4'), 'Line': (None, 'i4'),
'pressure': ('hPa', 'f4'), 'wind_speed': ('m s-1', 'f4'), 'wind_direction': ('degrees', 'f4')}
super().__init__(files_path, file_time_span, 'OR_ABI-L2-DMWF*'+'C'+band+'*.nc', band=band, elem_name=elem_name, params=params,
line_name=line_name, lat_name=lat_name, lon_name=lon_name, out_params=out_params, meta_dict=meta_dict)
def get_navigation(self):
# return GEOSNavigation(sub_lon=-75.2) ?
return GEOSNavigation(sub_lon=-75.0)
def get_datetime(self, pathname):
fname = os.path.split(pathname)[1]
toks = fname.split('_')
dtstr = toks[3]
dtstr = dtstr[:-3]
dto = datetime.datetime.strptime(dtstr, 's%Y%j%H%M').replace(tzinfo=timezone.utc)
return dto
class CarrStereo(AMVFiles):
def __init__(self, files_path, file_time_span, band='14'):
elem_name = 'Element'
line_name = 'Line'
lon_name = 'Lon'
lat_name = 'Lat'
out_params = ['Lon', 'Lat', 'Element', 'Line', 'V_3D_u', 'V_3D_v', 'H_3D', 'pres', 'Fcst_Spd', 'Fcst_Dir', 'SatZen',
'InversionFlag', 'CloudPhase', 'CloudType']
params = ['V_3D', 'H_3D', 'pres', 'Fcst_Spd', 'Fcst_Dir', 'SatZen',
'InversionFlag', 'CloudPhase', 'CloudType']
meta_dict = {'H_3D': ('m', 'f4'), 'pres': ('hPa', 'f4'), 'Fcst_Spd': ('m s-1', 'f4'),
'Fcst_Dir': ('degree', 'f4'),
'SatZen': ('degree', 'f4'), 'InversionFlag': (None, 'u1'),
'CloudPhase': (None, 'u1'), 'CloudType': (None, 'u1'),
'V_3D_u': ('m s-1', 'f4'), 'V_3D_v': ('m s-1', 'f4'), 'Lon': ('degrees east', 'f4'),
'Lat': ('degrees north', 'f4'), 'Element': (None, 'i4'), 'Line': (None, 'i4')}
super().__init__(files_path, file_time_span, 'tdw_qc_GOES*'+'ch_'+band+'.nc', band=band, elem_name=elem_name, params=params,
line_name=line_name, lat_name=lat_name, lon_name=lon_name, out_params=out_params, meta_dict=meta_dict)
def get_navigation(self):
return GEOSNavigation(sub_lon=-137.0)
def get_datetime(self, pathname):
fname = os.path.split(pathname)[1]
toks = fname.split('_')
dtstr = toks[3]
dto = datetime.datetime.strptime(dtstr, '%Y%j.%H%M.ch').replace(tzinfo=timezone.utc)
return dto
def get_datasource(files_path, file_time_span, source, band='14'):
if source == 'OPS':
return OPS(files_path, file_time_span, band=band)
elif source == 'FMWK':
return Framework(files_path, file_time_span, band=band)
elif source == 'CARR':
return CarrStereo(files_path, file_time_span, band=band)
elif source == 'FMWK_CLD_HGT':
return FrameworkCloudHeight(files_path, file_time_span)
elif source == 'FMWK_CLD_PHASE':
return FrameworkCloudPhase(files_path, file_time_span)
elif source == 'OPS_CLD_PHASE':
return OpsCloudPhase(files_path, file_time_span)
else:
raise GenericException('Unknown data source type')