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Commit 9d8929e4 authored by Marc-Antoine Drouin's avatar Marc-Antoine Drouin
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add CEREA CL51 configuration

parent 14c2b313
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Showing with 625 additions and 218 deletions
conf_vaisala_cl51_cereaLqualairR10mF30s.ini
View file @ 9d8929e4
......@@ -31,26 +31,83 @@ missing_float = -999.
missing_int = -9
check_scale = true
; Variables required by TOPROF chosen format
;==============================================================================
; Global attribute of the netCDF file
;------------------------------------------------------------------------------
[global]
site_location = paris/jussieu
site_location = PARIS,FRANCE
instrument_id = A
institution = CEREA (EDF/ENPC), IPSL (CNRS/ECole Polytechnique)
principal_investigator = SIRTA
instrument_type = CL51
title = Paris/jussieu VAISALA CL51 CEREA in QUALAIR station
history =
instrument_firmware_version = 1.302
wigos_station_id = 0-250-1001-75105006
wmo_id = 99015
instrument_serial_number = $reader_data$, instrument_id
instrument_firmware_version = $reader_data$, software_id
overlap_function = false
history =
hermes_history =
overlap_is_corrected = true
source = SIRTA
references =
principal_investigator = CEREA
title = PALAISEAU cl31 CEREA
institution = ENPC
source = Ground Based Remote Sensing
references = E-PROFILE Data Format Description Document
comment =
Conventions = CF-1.0, UKMO-1.0.2
Conventions = CF-1.7, UKMO-1.0.2
instrument_type = CL51
keywords = GCMD:EARTH SCIENCE, GCMD:ATMOSPHERE, GCMD:CLOUDS, GCMD:CLOUD PROPERTIES, GCMD:CLOUD BASE HEIGHT, GCMD:AEROSOLS, GCMD:AEROSOL BACKSCATTER, GCMD:SPECTRAL/ENGINEERING, GCMD:LIDAR, GCMD:LIDAR BACKSCATTER
id =
naming_authority =
processing_level = 1a raw data converted into normalized netCDF file
aknowledgement =
license = SIRTA data are accessible freely and free of cost, for public research and teaching applications.
- SIRTA data should only be distributed through SIRTA ftp and web access. SIRTA data not available online can be distributed by SIRTA instrument PIs.
- Distribution of SIRTA data by third parties is prohibited.
- The users of SIRTA data must verify that the data they are using is intended for publication refer to the advice of instrument PIs.
- The source of SIRTA data used in the framework of a publication must be mentioned in an explicit way in the acknowledgment section by a sentence of the type: « The authors would like to acknowledge SIRTA for providing the lidar data used in this study ».
- When mentioning or describing the SIRTA observatory in a publication, use the following reference: (Haeffelin et al., 2005)
- For the use of SIRTA data requiring a specific interpretation work and discussions essential to the exploitation of the data, it is required that relevant instrument PIs be proposed co-authorship in related publications.
- The use of data, in synergy with SIRTA data, originating from another organization (e.g. Meteo-France, AERONET, etc...) requires specific mention of that source of data
standard_name_vocabulary = CF Standard Name Table v36
date_created =
creator_name = sirta, CEREA
creator_email = sirtascience@lmd.polytechnique.fr, none
creator_url = https://sirta.ipsl.fr, https://www.cerea-lab.fr
creator_type = institution, institution
creator_institution = SIRTA CNRS/Ecole Polytechnique, ENPC
publisher_name = SIRTA (Site Instrumental de Recherche par Télédétection Atmosphérique)
publisher_email = sirtascience@ipsl.polytechnique.fr
publisher_url = http://www.sirta.fr
publisher_type = institution
publisher_institution = IPSL CNRS/Ecole Polytechnique
geospatial_bounds = POINT (48.85, 2.35)
geospatial_bounds_crs = EPSG:4326
geospatial_bounds_vertical_crs = EPSG:5829
geospatial_lat_min = 48.85
geospatial_lat_max = 48.85
geospatial_lat_units = degrees_north
geospatial_lat_resolution = 0 degree_north
geospatial_lon_min = 2.35
geospatial_lon_max = 2.35
geospatial_lon_units = degrees_east
geospatial_lon_resolution = 0 degree
geospatial_vertical_min = 10
geospatial_vertical_max = 15400
geospatial_vertical_positive = up
geospatial_vertical_units = m
geospatial_vertical_resolution = 10 meters
time_coverage_start =
time_coverage_end =
time_coverage_duration = P0000-00-01T00:00:00
time_coverage_resolution = P0000-00-00T00:00:30
date_modified =
date_issued =
date_metadata_modified = 2022-01-17T00:00:00Z
product_version = 1
keywords_vocabulary = GCMD:GCMD Keywords, CF:NetCDF COARDS Climate and Forecast Standard Names
platform = In Situ Land-based Platforms, GROUND-BASED OBSERVATIONS
platform_vocabulary = GCMD:GCMD Keywords
instrument = GCMD:Earth Remote Sensing Instruments, GCMD:Active Remote Sensing, GCMD:Profilers/Sounders, GCMD:Lidar/Laser Sounders, GCMD:CLOUD LIDAR, GCMD: LIDAR
instrument_vocabulary = GCMD:GCMD Keywords
cdm_data_type =
metadata_link =
; Dimensions
;------------------------------------------------------------------------------
......@@ -76,8 +133,8 @@ long_name = layer index of cloud base height
units = 1
value = $reader_data$, cbh_layer
[layer_clh]
dim = layer_clh
[layer_aerosol]
dim = layer_aerosol
type = $integer$
long_name = layer index of cloud layer height
units = 1
......@@ -89,20 +146,30 @@ value = $reader_data$, clh_layer
dim = time, range
type = $double$
long_name = normalized range corrected signal
units = 1e-8 sr^-1.m^-1
missing_value = -999.
_FillValue = -999.
units = V*m^2
missing_value = -999.9
_FillValue = -999.9
value = $reader_data$, rcs_0
detection_mode = analog
[bckgrd_rcs_0]
dim = time
type = $double$
long_name = background light at internal ADC input
units = mV
missing_value = -999.
_FillValue = -999.
missing_value = -999.9
_FillValue = -999.9
value = $reader_data$, bckgrd_rcs_0
[tilt_angle]
dim = time
type = $float$
long_name = instrument tilt angle from vertical
units = degree
missing_value = -999.9
_FillValue = -999.9
value = $reader_data$, tilt_angle
[cloud_base_height]
dim = time, layer
type = $integer$
......@@ -112,12 +179,13 @@ missing_value = -9
_FillValue = -9
value = $reader_data$, cbh
[time_resol]
dim = $none$
type = $integer$
long_name = time resolution
units = s
value = $reader_data$, time_resolution
[start_time]
dim = time
type = $time$
long_name = start time of measurements
units = days since 1970-01-01 00:00:00
value = $reader_data$, start_time
calendar = standard
[range_resol]
dim = $none$
......@@ -126,73 +194,47 @@ long_name = range resolution
units = m
value = $reader_data$, range_resol
[tilt_angle]
dim = time
type = $float$
long_name = instrument tilt angle from vertical
units = degree
missing_value = -999.
_FillValue = -999.
value = $reader_data$, tilt_angle
[l0_wavelength]
dim = $none$
type = $float$
long_name = laser 0 wavelength
units = nm
value = 910
[l0_width]
type = $float$
dim = $none$
type = $float$
long_name = laser 0 line width
units = nm
value = NAN
value = -999.9
[l0_beam_div]
type = $float$
dim = $none$
type = $float$
long_name = laser 0 beam divergence
units = rad
value = NAN
[l0_prf]
type = $float$
dim = $none$
long_name = laser 0 pulse repetition frequency
units = Hz
value = NAN
value = -999.9
[t0_fov]
type = $float$
dim = $none$
type = $float$
long_name = telescope 0 field of view
units = rad
value = NAN
value = -999.9
[t0_tilt]
type = $float$
[time_resol]
dim = $none$
long_name = telescope 0 tilt angle wrt nadir
units = degree
value = NAN
type = $integer$
long_name = time resolution
units = s
value = $reader_data$, time_resolution
[temperature_laser]
[l0_wavelength]
dim = $none$
type = $float$
long_name = laser temperature
units = K
dim = time
missing_value = -999.
_FillValue = -999.
value = $reader_data$, laser_temp
long_name = laser 0 wavelength
units = nm
value = 910
[start_time]
dim = time
type = $time$
long_name = start time of measurements
units = days since 1970-01-01 00:00:00
calendar = standard
value = $reader_data$, start_time
[l0_prf]
dim = $none$
type = $float$
long_name = laser 0 pulse repetition frequency
units = Hz
value = -999.9
[station_latitude]
dim = $none$
......@@ -200,6 +242,7 @@ type = $float$
long_name = latitude
units = degrees_north
value = 48.85
standard_name = latitude
[station_longitude]
dim = $none$
......@@ -207,58 +250,45 @@ type = $float$
long_name = longitude
units = degrees_east
value = 2.35
standard_name = longitude
[station_altitude]
dim = $none$
type = $float$
standard_name = altitude
long_name = altitude
units = m
value = 38
standard_name = altitude
; Additional data available in CL31 files
;==============================================================================
[calibration_factor]
dim = $none$
type = $float$
long_name = preliminary calibration factor
units = 1
comment = preliminary calibration factor to be applied to normalized range corrected signal (rcs_0) for display purpose only
missing_value = -999.
_FillValue = -999.
value = 1.e8
; 1d
[sum_rcs0]
dim = time
type = $float$
long_name = sum of detected and normalized backscatter
units = sr^-1
missing_value = -999.
_FillValue = -999.
missing_value = -999.9
_FillValue = -999.9
value = $reader_data$, integrated_rcs_0
[laser_energy]
dim = time
type = $float$
long_name = laser pulse energy, percent of nominal factory setting
units = %
missing_value = -999.
_FillValue = -999.
units = %%
missing_value = -999.9
_FillValue = -999.9
value = $reader_data$, laser_energy
[window_transmission]
dim = time
type = $float$
long_name = window transmission estimate
units = %
missing_value = -999.
_FillValue = -999.
units = %%
missing_value = -999.9
_FillValue = -999.9
value = $reader_data$, window_transmission
; 2d
[clh]
dim = time, layer_clh
dim = time, layer_aerosol
type = $integer$
long_name = cloud layer height
units = m
......@@ -267,27 +297,35 @@ _FillValue = -9
value = $reader_data$, clh
[cloud_amount]
dim = time, layer_aerosol
type = $short$
long_name = cloud fraction in eighths
units = 1
dim = time, layer_clh
missing_value = -9
_FillValue = -9
value = $reader_data$, cloud_amount
; string variables
[error_string]
[temperature_laser]
dim = time
type = $string$
long_name = alarm or warning status
units = 1
flag_values = 0, W, A
flags_meanings = None warning alarm
value = $reader_data$, alarm
type = $float$
long_name = laser temperature
units = K
missing_value = -999.9
_FillValue = -999.9
value = $reader_data$, laser_temp
[vertical_visibility]
dim = time
type = $integer$
long_name = vertical visibility
units = m
missing_value = -9
_FillValue = -9
value = $reader_data$, vertical_visibility
[alarm_infos]
[error_string]
dim = time
type = $string$
long_name = alarm or warning status
units = 1
value = $reader_data$, info_flags
\ No newline at end of file
value = $reader_data$, info_flags
conf_vaisala_cl51_cereaLz1R10mF30s.ini
View file @ 9d8929e4
......@@ -31,26 +31,83 @@ missing_float = -999.
missing_int = -9
check_scale = true
; Variables required by TOPROF chosen format
;==============================================================================
; Global attribute of the netCDF file
;------------------------------------------------------------------------------
[global]
site_location = palaiseau
site_location = PALAISEAU,FRANCE
instrument_id = A
institution = CEREA (EDF/ENPC), IPSL (CNRS/ECole Polytechnique)
principal_investigator = SIRTA
instrument_type = CL51
title = PALAISEAU VAISALA CL51 CEREA in SIRTA Z1
history =
instrument_firmware_version = unknown
wigos_station_id = 0-250-1001-07151
wmo_id = 07151
instrument_serial_number = $reader_data$, instrument_id
instrument_firmware_version = $reader_data$, software_id
overlap_function = false
history =
hermes_history =
overlap_is_corrected = true
source = SIRTA
references =
principal_investigator = CEREA
title = PALAISEAU cl31 CEREA
institution = ENPC
source = Ground Based Remote Sensing
references = E-PROFILE Data Format Description Document
comment =
Conventions = CF-1.0, UKMO-1.0.2
Conventions = CF-1.7, UKMO-1.0.2
instrument_type = CL51
keywords = GCMD:EARTH SCIENCE, GCMD:ATMOSPHERE, GCMD:CLOUDS, GCMD:CLOUD PROPERTIES, GCMD:CLOUD BASE HEIGHT, GCMD:AEROSOLS, GCMD:AEROSOL BACKSCATTER, GCMD:SPECTRAL/ENGINEERING, GCMD:LIDAR, GCMD:LIDAR BACKSCATTER
id =
naming_authority =
processing_level = 1a raw data converted into normalized netCDF file
aknowledgement =
license = SIRTA data are accessible freely and free of cost, for public research and teaching applications.
- SIRTA data should only be distributed through SIRTA ftp and web access. SIRTA data not available online can be distributed by SIRTA instrument PIs.
- Distribution of SIRTA data by third parties is prohibited.
- The users of SIRTA data must verify that the data they are using is intended for publication refer to the advice of instrument PIs.
- The source of SIRTA data used in the framework of a publication must be mentioned in an explicit way in the acknowledgment section by a sentence of the type: « The authors would like to acknowledge SIRTA for providing the lidar data used in this study ».
- When mentioning or describing the SIRTA observatory in a publication, use the following reference: (Haeffelin et al., 2005)
- For the use of SIRTA data requiring a specific interpretation work and discussions essential to the exploitation of the data, it is required that relevant instrument PIs be proposed co-authorship in related publications.
- The use of data, in synergy with SIRTA data, originating from another organization (e.g. Meteo-France, AERONET, etc...) requires specific mention of that source of data
standard_name_vocabulary = CF Standard Name Table v36
date_created =
creator_name = sirta, CEREA
creator_email = sirtascience@lmd.polytechnique.fr, none
creator_url = https://sirta.ipsl.fr, https://www.cerea-lab.fr
creator_type = institution, institution
creator_institution = SIRTA CNRS/Ecole Polytechnique, ENPC
publisher_name = SIRTA (Site Instrumental de Recherche par Télédétection Atmosphérique)
publisher_email = sirtascience@ipsl.polytechnique.fr
publisher_url = http://www.sirta.fr
publisher_type = institution
publisher_institution = IPSL CNRS/Ecole Polytechnique
geospatial_bounds = POINT (48.7, 2.2)
geospatial_bounds_crs = EPSG:4326
geospatial_bounds_vertical_crs = EPSG:5829
geospatial_lat_min = 48.7
geospatial_lat_max = 48.7
geospatial_lat_units = degrees_north
geospatial_lat_resolution = 0 degree_north
geospatial_lon_min = 2.2
geospatial_lon_max = 2.2
geospatial_lon_units = degrees_east
geospatial_lon_resolution = 0 degree
geospatial_vertical_min = 10
geospatial_vertical_max = 15400
geospatial_vertical_positive = up
geospatial_vertical_units = m
geospatial_vertical_resolution = 10 meters
time_coverage_start =
time_coverage_end =
time_coverage_duration = P0000-00-01T00:00:00
time_coverage_resolution = P0000-00-00T00:00:30
date_modified =
date_issued =
date_metadata_modified = 2022-01-17T00:00:00Z
product_version = 1
keywords_vocabulary = GCMD:GCMD Keywords, CF:NetCDF COARDS Climate and Forecast Standard Names
platform = In Situ Land-based Platforms, GROUND-BASED OBSERVATIONS
platform_vocabulary = GCMD:GCMD Keywords
instrument = GCMD:Earth Remote Sensing Instruments, GCMD:Active Remote Sensing, GCMD:Profilers/Sounders, GCMD:Lidar/Laser Sounders, GCMD:CLOUD LIDAR, GCMD: LIDAR
instrument_vocabulary = GCMD:GCMD Keywords
cdm_data_type =
metadata_link =
; Dimensions
;------------------------------------------------------------------------------
......@@ -76,8 +133,8 @@ long_name = layer index of cloud base height
units = 1
value = $reader_data$, cbh_layer
[layer_clh]
dim = layer_clh
[layer_aerosol]
dim = layer_aerosol
type = $integer$
long_name = layer index of cloud layer height
units = 1
......@@ -89,20 +146,30 @@ value = $reader_data$, clh_layer
dim = time, range
type = $double$
long_name = normalized range corrected signal
units = 1e-8 sr^-1.m^-1
missing_value = -999.
_FillValue = -999.
units = V*m^2
missing_value = -999.9
_FillValue = -999.9
value = $reader_data$, rcs_0
detection_mode = analog
[bckgrd_rcs_0]
dim = time
type = $double$
long_name = background light at internal ADC input
units = mV
missing_value = -999.
_FillValue = -999.
missing_value = -999.9
_FillValue = -999.9
value = $reader_data$, bckgrd_rcs_0
[tilt_angle]
dim = time
type = $float$
long_name = instrument tilt angle from vertical
units = degree
missing_value = -999.9
_FillValue = -999.9
value = $reader_data$, tilt_angle
[cloud_base_height]
dim = time, layer
type = $integer$
......@@ -112,12 +179,13 @@ missing_value = -9
_FillValue = -9
value = $reader_data$, cbh
[time_resol]
dim = $none$
type = $integer$
long_name = time resolution
units = s
value = $reader_data$, time_resolution
[start_time]
dim = time
type = $time$
long_name = start time of measurements
units = days since 1970-01-01 00:00:00
value = $reader_data$, start_time
calendar = standard
[range_resol]
dim = $none$
......@@ -126,73 +194,47 @@ long_name = range resolution
units = m
value = $reader_data$, range_resol
[tilt_angle]
dim = time
type = $float$
long_name = instrument tilt angle from vertical
units = degree
missing_value = -999.
_FillValue = -999.
value = $reader_data$, tilt_angle
[l0_wavelength]
dim = $none$
type = $float$
long_name = laser 0 wavelength
units = nm
value = 910
[l0_width]
type = $float$
dim = $none$
type = $float$
long_name = laser 0 line width
units = nm
value = NAN
value = -999.9
[l0_beam_div]
type = $float$
dim = $none$
type = $float$
long_name = laser 0 beam divergence
units = rad
value = NAN
[l0_prf]
type = $float$
dim = $none$
long_name = laser 0 pulse repetition frequency
units = Hz
value = NAN
value = -999.9
[t0_fov]
type = $float$
dim = $none$
type = $float$
long_name = telescope 0 field of view
units = rad
value = NAN
value = -999.9
[t0_tilt]
type = $float$
[time_resol]
dim = $none$
long_name = telescope 0 tilt angle wrt nadir
units = degree
value = NAN
type = $integer$
long_name = time resolution
units = s
value = $reader_data$, time_resolution
[temperature_laser]
[l0_wavelength]
dim = $none$
type = $float$
long_name = laser temperature
units = K
dim = time
missing_value = -999.
_FillValue = -999.