netcdf REOBS/reobs_sirta_2D_v3.1.1_19980723_230000_24y.nc { dimensions: time = UNLIMITED; // (216206 currently) nbnds = 2; altitude = 111; variables: long time(time=216206); :long_name = "Date"; :standard_name = "time"; :bounds = "time_bnds"; :units = "seconds since 1970-01-01"; :calendar = "standard"; :_ChunkSizes = 512U; // uint float altitude(altitude=111); :_FillValue = NaNf; // float :long_name = "altitude"; :units = "m"; :bounds = "altitude_bnds"; int target_cat_most_frequent(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "target_cat_most_frequent_percent, target_cat_second_most_frequent, target_cat_second_most_frequent_percent"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Target categorization most frequent occurence"; :units = "inherit"; :comment = "This variable contains information on the nature of the targets at each pixel, thereby facilitating the application of algorithms that work with only one type of target. The information is in the form of an array of bits, each of which states either whether a certain type of particle is present (e.g. aerosols), or the whether some of the target particles have a particular property. The definitions of each bit are given in the definition attribute. Bit 0 is the least significant.\\nBit 0: Small liquid droplets are present.\\nBit 1: Falling hydrometeors are present if Bit 2 is set then these are most likely ice particles, otherwise they are drizzle or rain drops.\\nBit 2: Wet-bulb temperature is less than 0 degrees C, implying the phase of Bit-1 particles.\\nBit 3: Melting ice particles are present.\\nBit 4: Aerosol particles are present and visible to the lidar.\\nBit 5: Insects are present and visible to the radar."; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint long time_bnds(time=216206, nbnds=2); :bounds = "time_bnds"; :_ChunkSizes = 1U, 2U; // uint long altitude_bnds(altitude=111, nbnds=2); :bounds = "altitude_bnds"; int target_quality_most_frequent(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "target_quality_most_frequent_percent, target_quality_second_most_frequent, target_quality_second_most_frequent_percent"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Quality bits most frequent occurence"; :units = "inherit"; :comment = "This variable contains information on the quality of the data at each pixel. The information is in the form of an array of bits, and the definitions of each bit are given in the definition attribute. Bit 0 is the least significant.\\nBit 0: An echo is detected by the radar.\\nBit 1: An echo is detected by the lidar.\\nBit 2: The apparent echo detected by the radar is ground clutter or some other non-atmospheric artifact.\\nBit 3: The lidar echo is due to clear-air molecular scattering.\\nBit 4: Liquid water cloud, rainfall or melting ice below this pixel will have caused radar and lidar attenuation if bit 5 is set then a correction for the radar attenuation has been performed otherwise do not trust the absolute values of reflectivity factor. No correction is performed for lidar attenuation.\\nBit 5: Radar reflectivity has been corrected for liquid-water attenuation using the microwave radiometer measurements of liquid water path and the lidar estimation of the location of liquid water cloud be aware that errors in reflectivity may result."; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint long target_cat_most_frequent_percent(time=216206, altitude=111); :_FillValue = -999L; // long :ancillary_variables = "target_cat_most_frequent, target_cat_second_most_frequent, target_cat_second_most_frequent_percent"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Target categorization most frequent occurence percent"; :units = "inherit"; :comment = "This variable contains information on the nature of the targets at each pixel, thereby facilitating the application of algorithms that work with only one type of target. The information is in the form of an array of bits, each of which states either whether a certain type of particle is present (e.g. aerosols), or the whether some of the target particles have a particular property. The definitions of each bit are given in the definition attribute. Bit 0 is the least significant.\\nBit 0: Small liquid droplets are present.\\nBit 1: Falling hydrometeors are present if Bit 2 is set then these are most likely ice particles, otherwise they are drizzle or rain drops.\\nBit 2: Wet-bulb temperature is less than 0 degrees C, implying the phase of Bit-1 particles.\\nBit 3: Melting ice particles are present.\\nBit 4: Aerosol particles are present and visible to the lidar.\\nBit 5: Insects are present and visible to the radar."; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint long target_quality_most_frequent_percent(time=216206, altitude=111); :_FillValue = -999L; // long :ancillary_variables = "target_quality_most_frequent, target_quality_second_most_frequent, target_quality_second_most_frequent_percent"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Quality bits most frequent occurence percent"; :units = "inherit"; :comment = "This variable contains information on the quality of the data at each pixel. The information is in the form of an array of bits, and the definitions of each bit are given in the definition attribute. Bit 0 is the least significant.\\nBit 0: An echo is detected by the radar.\\nBit 1: An echo is detected by the lidar.\\nBit 2: The apparent echo detected by the radar is ground clutter or some other non-atmospheric artifact.\\nBit 3: The lidar echo is due to clear-air molecular scattering.\\nBit 4: Liquid water cloud, rainfall or melting ice below this pixel will have caused radar and lidar attenuation if bit 5 is set then a correction for the radar attenuation has been performed otherwise do not trust the absolute values of reflectivity factor. No correction is performed for lidar attenuation.\\nBit 5: Radar reflectivity has been corrected for liquid-water attenuation using the microwave radiometer measurements of liquid water path and the lidar estimation of the location of liquid water cloud be aware that errors in reflectivity may result."; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint int target_cat_second_most_frequent(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "target_cat_most_frequent, target_cat_most_frequent_percent, target_cat_second_most_frequent_percent"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Target categorization second most frequent occurence"; :units = "inherit"; :comment = "This variable contains information on the nature of the targets at each pixel, thereby facilitating the application of algorithms that work with only one type of target. The information is in the form of an array of bits, each of which states either whether a certain type of particle is present (e.g. aerosols), or the whether some of the target particles have a particular property. The definitions of each bit are given in the definition attribute. Bit 0 is the least significant.\\nBit 0: Small liquid droplets are present.\\nBit 1: Falling hydrometeors are present if Bit 2 is set then these are most likely ice particles, otherwise they are drizzle or rain drops.\\nBit 2: Wet-bulb temperature is less than 0 degrees C, implying the phase of Bit-1 particles.\\nBit 3: Melting ice particles are present.\\nBit 4: Aerosol particles are present and visible to the lidar.\\nBit 5: Insects are present and visible to the radar."; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint int target_quality_second_most_frequent(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "target_quality_most_frequent, target_quality_most_frequent_percent, target_quality_second_most_frequent_percent"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Quality bits second most frequent occurence"; :units = "inherit"; :comment = "This variable contains information on the quality of the data at each pixel. The information is in the form of an array of bits, and the definitions of each bit are given in the definition attribute. Bit 0 is the least significant.\\nBit 0: An echo is detected by the radar.\\nBit 1: An echo is detected by the lidar.\\nBit 2: The apparent echo detected by the radar is ground clutter or some other non-atmospheric artifact.\\nBit 3: The lidar echo is due to clear-air molecular scattering.\\nBit 4: Liquid water cloud, rainfall or melting ice below this pixel will have caused radar and lidar attenuation if bit 5 is set then a correction for the radar attenuation has been performed otherwise do not trust the absolute values of reflectivity factor. No correction is performed for lidar attenuation.\\nBit 5: Radar reflectivity has been corrected for liquid-water attenuation using the microwave radiometer measurements of liquid water path and the lidar estimation of the location of liquid water cloud be aware that errors in reflectivity may result."; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint long target_cat_second_most_frequent_percent(time=216206, altitude=111); :_FillValue = -999L; // long :ancillary_variables = "target_cat_most_frequent, target_cat_most_frequent_percent, target_cat_second_most_frequent"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Target categorization second most frequent occurence percent"; :units = "inherit"; :comment = "This variable contains information on the nature of the targets at each pixel, thereby facilitating the application of algorithms that work with only one type of target. The information is in the form of an array of bits, each of which states either whether a certain type of particle is present (e.g. aerosols), or the whether some of the target particles have a particular property. The definitions of each bit are given in the definition attribute. Bit 0 is the least significant.\\nBit 0: Small liquid droplets are present.\\nBit 1: Falling hydrometeors are present if Bit 2 is set then these are most likely ice particles, otherwise they are drizzle or rain drops.\\nBit 2: Wet-bulb temperature is less than 0 degrees C, implying the phase of Bit-1 particles.\\nBit 3: Melting ice particles are present.\\nBit 4: Aerosol particles are present and visible to the lidar.\\nBit 5: Insects are present and visible to the radar."; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint long target_quality_second_most_frequent_percent(time=216206, altitude=111); :_FillValue = -999L; // long :ancillary_variables = "target_quality_most_frequent, target_quality_most_frequent_percent, target_quality_second_most_frequent"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Quality bits second most frequent occurence percent"; :units = "inherit"; :comment = "This variable contains information on the quality of the data at each pixel. The information is in the form of an array of bits, and the definitions of each bit are given in the definition attribute. Bit 0 is the least significant.\\nBit 0: An echo is detected by the radar.\\nBit 1: An echo is detected by the lidar.\\nBit 2: The apparent echo detected by the radar is ground clutter or some other non-atmospheric artifact.\\nBit 3: The lidar echo is due to clear-air molecular scattering.\\nBit 4: Liquid water cloud, rainfall or melting ice below this pixel will have caused radar and lidar attenuation if bit 5 is set then a correction for the radar attenuation has been performed otherwise do not trust the absolute values of reflectivity factor. No correction is performed for lidar attenuation.\\nBit 5: Radar reflectivity has been corrected for liquid-water attenuation using the microwave radiometer measurements of liquid water path and the lidar estimation of the location of liquid water cloud be aware that errors in reflectivity may result."; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint int target_classification_most_frequent(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "target_classification_most_frequent_percent, target_classification_second_most_frequent, target_classification_second_most_frequent_percent"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Target classification most frequent occurence"; :units = "inherit"; :comment = "This variable provides the main atmospheric target classifications that can be distinguished by radar and lidar.\\nValue 0: Clear sky.\\nValue 1: Cloud liquid droplets only.\\nValue 2: Drizzle or rain.\\nValue 3: Drizzle or rain coexisting with cloud liquid droplets.\\nValue 4: Ice particles.\\nValue 5: Ice coexisting with supercooled liquid droplets.\\nValue 6: Melting ice particles.\\nValue 7: Melting ice particles coexisting with cloud liquid droplets.\\nValue 8: Aerosol particles, no cloud or precipitation.\\nValue 9: Insects, no cloud or precipitation.\\nValue 10: Aerosol coexisting with insects, no cloud or precipitation"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint long target_classification_most_frequent_percent(time=216206, altitude=111); :_FillValue = -999L; // long :ancillary_variables = "target_classification_most_frequent, target_classification_second_most_frequent, target_classification_second_most_frequent_percent"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Target classification most frequent occurence percent"; :units = "inherit"; :comment = "This variable provides the main atmospheric target classifications that can be distinguished by radar and lidar.\\nValue 0: Clear sky.\\nValue 1: Cloud liquid droplets only.\\nValue 2: Drizzle or rain.\\nValue 3: Drizzle or rain coexisting with cloud liquid droplets.\\nValue 4: Ice particles.\\nValue 5: Ice coexisting with supercooled liquid droplets.\\nValue 6: Melting ice particles.\\nValue 7: Melting ice particles coexisting with cloud liquid droplets.\\nValue 8: Aerosol particles, no cloud or precipitation.\\nValue 9: Insects, no cloud or precipitation.\\nValue 10: Aerosol coexisting with insects, no cloud or precipitation"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint int target_classification_second_most_frequent(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "target_classification_most_frequent, target_classification_most_frequent_percent, target_classification_second_most_frequent_percent"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Target classification second most frequent occurence"; :units = "inherit"; :comment = "This variable provides the main atmospheric target classifications that can be distinguished by radar and lidar.\\nValue 0: Clear sky.\\nValue 1: Cloud liquid droplets only.\\nValue 2: Drizzle or rain.\\nValue 3: Drizzle or rain coexisting with cloud liquid droplets.\\nValue 4: Ice particles.\\nValue 5: Ice coexisting with supercooled liquid droplets.\\nValue 6: Melting ice particles.\\nValue 7: Melting ice particles coexisting with cloud liquid droplets.\\nValue 8: Aerosol particles, no cloud or precipitation.\\nValue 9: Insects, no cloud or precipitation.\\nValue 10: Aerosol coexisting with insects, no cloud or precipitation"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint long target_classification_second_most_frequent_percent(time=216206, altitude=111); :_FillValue = -999L; // long :ancillary_variables = "target_classification_most_frequent, target_classification_most_frequent_percent, target_classification_second_most_frequent"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Target classification second most frequent occurence percent"; :units = "inherit"; :comment = "This variable provides the main atmospheric target classifications that can be distinguished by radar and lidar.\\nValue 0: Clear sky.\\nValue 1: Cloud liquid droplets only.\\nValue 2: Drizzle or rain.\\nValue 3: Drizzle or rain coexisting with cloud liquid droplets.\\nValue 4: Ice particles.\\nValue 5: Ice coexisting with supercooled liquid droplets.\\nValue 6: Melting ice particles.\\nValue 7: Melting ice particles coexisting with cloud liquid droplets.\\nValue 8: Aerosol particles, no cloud or precipitation.\\nValue 9: Insects, no cloud or precipitation.\\nValue 10: Aerosol coexisting with insects, no cloud or precipitation"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint float cbh(time=216206); :_FillValue = NaNf; // float :long_name = "Height of cloud base above ground level"; :units = "m"; :ancillary_variables = "cbh_median, cbh_min, cbh_max, cbh_nb, cbh_q25, cbh_q75"; :cell_methods = "time:mean"; :theme = "clouds"; :_ChunkSizes = 1020U; // uint float cth(time=216206); :_FillValue = NaNf; // float :long_name = "Height of cloud top above ground level"; :units = "m"; :ancillary_variables = "cth_median, cth_min, cth_max, cth_nb, cth_q25, cth_q75"; :cell_methods = "time:mean"; :theme = "clouds"; :_ChunkSizes = 1020U; // uint float cbh_median(time=216206); :_FillValue = NaNf; // float :ancillary_variables = "cbh, cbh_min, cbh_max, cbh_nb, cbh_q25, cbh_q75"; :cell_methods = "time:mean"; :long_name = "Height of cloud base above ground level median"; :units = "inherit"; :theme = "clouds"; :_ChunkSizes = 1020U; // uint float cth_median(time=216206); :_FillValue = NaNf; // float :ancillary_variables = "cth, cth_min, cth_max, cth_nb, cth_q25, cth_q75"; :cell_methods = "time:mean"; :long_name = "Height of cloud top above ground level median"; :units = "inherit"; :theme = "clouds"; :_ChunkSizes = 1020U; // uint float cbh_min(time=216206); :_FillValue = NaNf; // float :ancillary_variables = "cbh, cbh_median, cbh_max, cbh_nb, cbh_q25, cbh_q75"; :cell_methods = "time:mean"; :long_name = "Height of cloud base above ground level minimum"; :units = "inherit"; :theme = "clouds"; :_ChunkSizes = 1020U; // uint float cth_min(time=216206); :_FillValue = NaNf; // float :ancillary_variables = "cth, cth_median, cth_max, cth_nb, cth_q25, cth_q75"; :cell_methods = "time:mean"; :long_name = "Height of cloud top above ground level minimum"; :units = "inherit"; :theme = "clouds"; :_ChunkSizes = 1020U; // uint float cbh_max(time=216206); :_FillValue = NaNf; // float :ancillary_variables = "cbh, cbh_median, cbh_min, cbh_nb, cbh_q25, cbh_q75"; :cell_methods = "time:mean"; :long_name = "Height of cloud base above ground level maximum"; :units = "inherit"; :theme = "clouds"; :_ChunkSizes = 1020U; // uint float cth_max(time=216206); :_FillValue = NaNf; // float :ancillary_variables = "cth, cth_median, cth_min, cth_nb, cth_q25, cth_q75"; :cell_methods = "time:mean"; :long_name = "Height of cloud top above ground level maximum"; :units = "inherit"; :theme = "clouds"; :_ChunkSizes = 1020U; // uint float cbh_q25(time=216206); :_FillValue = NaNf; // float :ancillary_variables = "cbh, cbh_median, cbh_min, cbh_max, cbh_nb, cbh_q75"; :cell_methods = "time:mean"; :long_name = "Height of cloud base above ground level quantile 25%"; :units = "inherit"; :theme = "clouds"; :_ChunkSizes = 1020U; // uint float cth_q25(time=216206); :_FillValue = NaNf; // float :ancillary_variables = "cth, cth_median, cth_min, cth_max, cth_nb, cth_q75"; :cell_methods = "time:mean"; :long_name = "Height of cloud top above ground level quantile 25%"; :units = "inherit"; :theme = "clouds"; :_ChunkSizes = 1020U; // uint float cbh_q75(time=216206); :_FillValue = NaNf; // float :ancillary_variables = "cbh, cbh_median, cbh_min, cbh_max, cbh_nb, cbh_q25"; :cell_methods = "time:mean"; :long_name = "Height of cloud base above ground level quantile 75%"; :units = "inherit"; :theme = "clouds"; :_ChunkSizes = 1020U; // uint float cth_q75(time=216206); :_FillValue = NaNf; // float :ancillary_variables = "cth, cth_median, cth_min, cth_max, cth_nb, cth_q25"; :cell_methods = "time:mean"; :long_name = "Height of cloud top above ground level quantile 75%"; :units = "inherit"; :theme = "clouds"; :_ChunkSizes = 1020U; // uint int cbh_nb(time=216206); :_FillValue = -999; // int :ancillary_variables = "cbh, cbh_median, cbh_min, cbh_max, cbh_q25, cbh_q75"; :cell_methods = "time:mean"; :long_name = "Height of cloud base above ground level number"; :units = "1"; :theme = "clouds"; :_ChunkSizes = 1020U; // uint int cth_nb(time=216206); :_FillValue = -999; // int :ancillary_variables = "cth, cth_median, cth_min, cth_max, cth_q25, cth_q75"; :cell_methods = "time:mean"; :long_name = "Height of cloud top above ground level number"; :units = "1"; :theme = "clouds"; :_ChunkSizes = 1020U; // uint float Do(time=216206, altitude=111); :_FillValue = NaNf; // float :long_name = "Drizzle median diameter"; :units = "m"; :comment = "https://doi.org/10.21105/joss.02123"; :ancillary_variables = "Do_std, Do_nb"; :cell_methods = "time:mean, altitude:mean"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint float mu(time=216206, altitude=111); :_FillValue = NaNf; // float :long_name = "Drizzle droplet size distribution shape parameter"; :units = "1"; :comment = "https://doi.org/10.21105/joss.02123"; :ancillary_variables = "mu_std, mu_nb"; :cell_methods = "time:mean, altitude:mean"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint float drizzle_N(time=216206, altitude=111); :units = "m^-3"; :ancillary_variables = "drizzle_N_std, drizzle_N_nb"; :cell_methods = "time:mean, altitude:mean"; :theme = "clouds"; :_FillValue = NaNf; // float :long_name = "Drizzle number concentration"; :_ChunkSizes = 1U, 111U; // uint float drizzle_lwc(time=216206, altitude=111); :_FillValue = NaNf; // float :long_name = "Drizzle liquid water content"; :units = "kg.m^-3"; :ancillary_variables = "drizzle_lwc_std, drizzle_lwc_nb"; :cell_methods = "time:mean, altitude:mean"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint float v_drizzle(time=216206, altitude=111); :_FillValue = NaNf; // float :long_name = "Drizzle droplet fall velocity"; :units = "m.s^-1"; :comment = "Positive values are towards the ground"; :ancillary_variables = "v_drizzle_std, v_drizzle_nb"; :cell_methods = "time:mean, altitude:mean"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint float v_air(time=216206, altitude=111); :_FillValue = NaNf; // float :long_name = "Vertical air velocity"; :units = "m.s^-1"; :comment = "Positive values are towards the sky"; :ancillary_variables = "v_air_std, v_air_nb"; :cell_methods = "time:mean, altitude:mean"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint float Do_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "Do, Do_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Drizzle median diameter standard deviation"; :units = "inherit"; :comment = "https://doi.org/10.21105/joss.02123"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint float mu_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "mu, mu_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Drizzle droplet size distribution shape parameter standard deviation"; :units = "inherit"; :comment = "https://doi.org/10.21105/joss.02123"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint float drizzle_N_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "drizzle_N, drizzle_N_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Drizzle number concentration standard deviation"; :theme = "clouds"; :units = "inherit"; :_ChunkSizes = 1U, 111U; // uint float drizzle_lwc_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "drizzle_lwc, drizzle_lwc_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Drizzle liquid water content standard deviation"; :units = "inherit"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint float v_drizzle_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "v_drizzle, v_drizzle_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Drizzle droplet fall velocity standard deviation"; :units = "inherit"; :comment = "Positive values are towards the ground"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint float v_air_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "v_air, v_air_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Vertical air velocity standard deviation"; :units = "inherit"; :comment = "Positive values are towards the sky"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint int Do_nb(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "Do, Do_std"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Drizzle median diameter number"; :units = "1"; :comment = "https://doi.org/10.21105/joss.02123"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint int mu_nb(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "mu, mu_std"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Drizzle droplet size distribution shape parameter number"; :units = "1"; :comment = "https://doi.org/10.21105/joss.02123"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint int drizzle_N_nb(time=216206, altitude=111); :cell_methods = "time:mean, altitude:mean"; :long_name = "Drizzle number concentration number"; :units = "1"; :theme = "clouds"; :_FillValue = -999; // int :ancillary_variables = "drizzle_N, drizzle_N_std"; :_ChunkSizes = 1U, 111U; // uint int drizzle_lwc_nb(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "drizzle_lwc, drizzle_lwc_std"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Drizzle liquid water content number"; :units = "1"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint int v_drizzle_nb(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "v_drizzle, v_drizzle_std"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Drizzle droplet fall velocity number"; :units = "1"; :comment = "Positive values are towards the ground"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint int v_air_nb(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "v_air, v_air_std"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Vertical air velocity number"; :units = "1"; :comment = "Positive values are towards the sky"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint float iwc(time=216206, altitude=111); :_FillValue = NaNf; // float :long_name = "Liquid Water Content"; :units = "kg m-3"; :comment = "This variable was calculated from the 94-GHz radar reflectivity factor after correction for gaseous attenuation, and temperature taken from a forecast model. Iwc is processed when \"categorization\" data has diagnosed that the radar echo is due to ice, but note that in some cases supercooled drizzle will erroneously be identified as ice. Missing data indicates either that ice cloud was present but it was only detected by the lidar so its ice water content could not be estimated, or that there was rain below the ice associated with uncertain attenuation of the reflectivities in the ice."; :ancillary_variables = "iwc_std, iwc_nb"; :cell_methods = "time:mean, altitude:mean"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint float iwc_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "iwc, iwc_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Liquid Water Content standard deviation"; :units = "inherit"; :comment = "This variable was calculated from the 94-GHz radar reflectivity factor after correction for gaseous attenuation, and temperature taken from a forecast model. Iwc is processed when \"categorization\" data has diagnosed that the radar echo is due to ice, but note that in some cases supercooled drizzle will erroneously be identified as ice. Missing data indicates either that ice cloud was present but it was only detected by the lidar so its ice water content could not be estimated, or that there was rain below the ice associated with uncertain attenuation of the reflectivities in the ice."; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint int iwc_nb(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "iwc, iwc_std"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Liquid Water Content number"; :units = "1"; :comment = "This variable was calculated from the 94-GHz radar reflectivity factor after correction for gaseous attenuation, and temperature taken from a forecast model. Iwc is processed when \"categorization\" data has diagnosed that the radar echo is due to ice, but note that in some cases supercooled drizzle will erroneously be identified as ice. Missing data indicates either that ice cloud was present but it was only detected by the lidar so its ice water content could not be estimated, or that there was rain below the ice associated with uncertain attenuation of the reflectivities in the ice."; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint double beta(time=216206, altitude=111); :_FillValue = NaN; // double :ancillary_variables = "beta_std, beta_nb"; :_ChunkSizes = 1U, 111U; // uint double beta_std(time=216206, altitude=111); :_FillValue = NaN; // double :ancillary_variables = "beta, beta_nb"; :_ChunkSizes = 1U, 111U; // uint double beta_nb(time=216206, altitude=111); :_FillValue = NaN; // double :ancillary_variables = "beta, beta_std"; :_ChunkSizes = 1U, 111U; // uint float lwc(time=216206, altitude=111); :_FillValue = NaNf; // float :long_name = "Liquid Water Content"; :units = "kg m-3"; :comment = "This variable was calculated for the profiles where the categorization data has diagnosed that liquid water is present and liquid water path is available from a coincident microwave radiometer. The model temperature and pressure were used to estimate the theoretical adiabatic liquid water content gradient for each cloud base and the adiabatic liquid water content is then scaled that its integral matches the radiometer measurement so that the liquid water content now follows a quasi-adiabatic profile."; :ancillary_variables = "lwc_std, lwc_nb"; :cell_methods = "time:mean, altitude:mean"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint float lwc_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "lwc, lwc_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Liquid Water Content standard deviation"; :units = "inherit"; :comment = "This variable was calculated for the profiles where the categorization data has diagnosed that liquid water is present and liquid water path is available from a coincident microwave radiometer. The model temperature and pressure were used to estimate the theoretical adiabatic liquid water content gradient for each cloud base and the adiabatic liquid water content is then scaled that its integral matches the radiometer measurement so that the liquid water content now follows a quasi-adiabatic profile."; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint int lwc_nb(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "lwc, lwc_std"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Liquid Water Content number"; :units = "1"; :comment = "This variable was calculated for the profiles where the categorization data has diagnosed that liquid water is present and liquid water path is available from a coincident microwave radiometer. The model temperature and pressure were used to estimate the theoretical adiabatic liquid water content gradient for each cloud base and the adiabatic liquid water content is then scaled that its integral matches the radiometer measurement so that the liquid water content now follows a quasi-adiabatic profile."; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint float lwp(time=216206); :_FillValue = NaNf; // float :standard_name = "atmosphere_mass_content_of_cloud_liquid_water"; :long_name = "Liquid Water Path"; :units = "kg.m^-2"; :comment = "Content indicates a quantity per unit area. The atmosphere content of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used"; :instrument = "radiometer-physics-gmbh_hatpro-g2(20100301-now)"; :cell_methods = "time: mean"; :coverage_content_type = "physicalMeasurement"; :theme = "clouds"; :ancillary_variables = "lwp_std, lwp_nb"; :_ChunkSizes = 1020U; // uint float lwp_std(time=216206); :_FillValue = NaNf; // float :ancillary_variables = "lwp, lwp_nb"; :cell_methods = "time: standard_deviation"; :long_name = "Liquid Water Path standard deviation"; :units = "inherit"; :comment = "Content indicates a quantity per unit area. The atmosphere content of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used"; :instrument = "radiometer-physics-gmbh_hatpro-g2(20100301-now)"; :coverage_content_type = "physicalMeasurement"; :theme = "clouds"; :_ChunkSizes = 1020U; // uint int lwp_nb(time=216206); :_FillValue = -999; // int :ancillary_variables = "lwp, lwp_std"; :cell_methods = "time: number"; :long_name = "Liquid Water Path number"; :units = "1"; :comment = "Content indicates a quantity per unit area. The atmosphere content of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used"; :instrument = "radiometer-physics-gmbh_hatpro-g2(20100301-now)"; :coverage_content_type = "physicalMeasurement"; :theme = "clouds"; :_ChunkSizes = 1020U; // uint float Zh(time=216206, altitude=111); :_FillValue = NaNf; // float :long_name = "Radar reflectivity factor"; :units = "dbZ"; :comment = "Calibrated reflectivity. Calibration convention: in the absence of attenuation, a cloud at 273 K containing one million 100-micron droplets per cubic metre will have a reflectivity of 0 dBZ at all frequencies."; :ancillary_variables = "Zh_std, Zh_nb"; :cell_methods = "time:mean, altitude:mean"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint float v(time=216206, altitude=111); :_FillValue = NaNf; // float :long_name = "Doppler velocity"; :units = "m.s^-1"; :comment = "This parameter is the radial component of the velocity, with positive velocities are away from the radar."; :ancillary_variables = "v_std, v_nb"; :cell_methods = "time:mean, altitude:mean"; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint float Zh_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "Zh, Zh_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Radar reflectivity factor standard deviation"; :units = "inherit"; :comment = "Calibrated reflectivity. Calibration convention: in the absence of attenuation, a cloud at 273 K containing one million 100-micron droplets per cubic metre will have a reflectivity of 0 dBZ at all frequencies."; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint float v_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "v, v_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Doppler velocity standard deviation"; :units = "inherit"; :comment = "This parameter is the radial component of the velocity, with positive velocities are away from the radar."; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint int Zh_nb(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "Zh, Zh_std"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Radar reflectivity factor number"; :units = "1"; :comment = "Calibrated reflectivity. Calibration convention: in the absence of attenuation, a cloud at 273 K containing one million 100-micron droplets per cubic metre will have a reflectivity of 0 dBZ at all frequencies."; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint int v_nb(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "v, v_std"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Doppler velocity number"; :units = "1"; :comment = "This parameter is the radial component of the velocity, with positive velocities are away from the radar."; :theme = "clouds"; :_ChunkSizes = 1U, 111U; // uint float ps_rs(time=216206, altitude=111); :_FillValue = NaNf; // float :standard_name = "air_pressure"; :long_name = "Air pressure"; :unit = "hPa"; :comment = "Calculated with Laplace equation stating for the altitude provided with the GPS and the temperature measured by the radiosonde sensor. The ground pressure used to start the calculation of the pressure profile is the atmospheric pressure measured by the standard meteorological (named air_pressure)."; :cell_methods = "time:mean, altitude:mean"; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :ancillary_variables = "ps_rs_std, ps_rs_nb"; :_ChunkSizes = 1U, 111U; // uint float ta_rs(time=216206, altitude=111); :_FillValue = NaNf; // float :standard_name = "air_temperature"; :long_name = "Air temperature"; :unit = "Celsius"; :comment = "Measured by radiosonde. Best product or final product L2 GDP GRUAN"; :cell_methods = "time:mean, altitude:mean"; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :ancillary_variables = "ta_rs_std, ta_rs_nb"; :_ChunkSizes = 1U, 111U; // uint float rh_rs(time=216206, altitude=111); :_FillValue = NaNf; // float :standard_name = "relative_humidity"; :long_name = "Relative Humidity"; :unit = "%"; :comment = "Measured by radiosonde. Best product or final product L2 GDP GRUAN"; :cell_methods = "time:mean, altitude:mean"; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :ancillary_variables = "rh_rs_std, rh_rs_nb"; :_ChunkSizes = 1U, 111U; // uint float wd_rs(time=216206, altitude=111); :_FillValue = NaNf; // float :standard_name = "wind_from_direction"; :long_name = "Wind from direction"; :unit = "degree"; :comment = "In meteorological reports, the direction of the wind vector is usually (but not always) given as the direction from which it is blowing 57(wind_from_direction) (westerly, northerly, etc.). The direction is a bearing in the usual geographical sense, measured positive clockwise from due north."; :cell_methods = "time:mean, altitude:mean"; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :ancillary_variables = "wd_rs_std, wd_rs_nb"; :_ChunkSizes = 1U, 111U; // uint float ws_rs(time=216206, altitude=111); :_FillValue = NaNf; // float :standard_name = "wind_speed"; :long_name = "Horizontal wind speed"; :unit = "m.s^-1"; :cell_methods = "time:mean, altitude:mean"; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :ancillary_variables = "ws_rs_std, ws_rs_nb"; :_ChunkSizes = 1U, 111U; // uint float u_rs(time=216206, altitude=111); :_FillValue = NaNf; // float :standard_name = "eastward_wind"; :long_name = "Eastward wind"; :unit = "m.s^-1"; :cell_methods = "time:mean, altitude:mean"; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :ancillary_variables = "u_rs_std, u_rs_nb"; :_ChunkSizes = 1U, 111U; // uint float v_rs(time=216206, altitude=111); :_FillValue = NaNf; // float :standard_name = "northward_wind"; :long_name = "Northward wind"; :unit = "m.s^-1"; :cell_methods = "time:mean, altitude:mean"; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :ancillary_variables = "v_rs_std, v_rs_nb"; :_ChunkSizes = 1U, 111U; // uint float ps_rs_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "ps_rs, ps_rs_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Air pressure standard deviation"; :unit = "inherit"; :comment = "Calculated with Laplace equation stating for the altitude provided with the GPS and the temperature measured by the radiosonde sensor. The ground pressure used to start the calculation of the pressure profile is the atmospheric pressure measured by the standard meteorological (named air_pressure)."; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :_ChunkSizes = 1U, 111U; // uint float ta_rs_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "ta_rs, ta_rs_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Air temperature standard deviation"; :unit = "inherit"; :comment = "Measured by radiosonde. Best product or final product L2 GDP GRUAN"; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :_ChunkSizes = 1U, 111U; // uint float rh_rs_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "rh_rs, rh_rs_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Relative Humidity standard deviation"; :unit = "inherit"; :comment = "Measured by radiosonde. Best product or final product L2 GDP GRUAN"; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :_ChunkSizes = 1U, 111U; // uint float wd_rs_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "wd_rs, wd_rs_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Wind from direction standard deviation"; :unit = "inherit"; :comment = "In meteorological reports, the direction of the wind vector is usually (but not always) given as the direction from which it is blowing 57(wind_from_direction) (westerly, northerly, etc.). The direction is a bearing in the usual geographical sense, measured positive clockwise from due north."; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :_ChunkSizes = 1U, 111U; // uint float ws_rs_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "ws_rs, ws_rs_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Horizontal wind speed standard deviation"; :unit = "inherit"; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :_ChunkSizes = 1U, 111U; // uint float u_rs_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "u_rs, u_rs_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Eastward wind standard deviation"; :unit = "inherit"; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :_ChunkSizes = 1U, 111U; // uint float v_rs_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "v_rs, v_rs_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Northward wind standard deviation"; :unit = "inherit"; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :_ChunkSizes = 1U, 111U; // uint int ps_rs_nb(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "ps_rs, ps_rs_std"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Air pressure number"; :unit = "1"; :comment = "Calculated with Laplace equation stating for the altitude provided with the GPS and the temperature measured by the radiosonde sensor. The ground pressure used to start the calculation of the pressure profile is the atmospheric pressure measured by the standard meteorological (named air_pressure)."; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :_ChunkSizes = 1U, 111U; // uint int ta_rs_nb(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "ta_rs, ta_rs_std"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Air temperature number"; :unit = "1"; :comment = "Measured by radiosonde. Best product or final product L2 GDP GRUAN"; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :_ChunkSizes = 1U, 111U; // uint int rh_rs_nb(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "rh_rs, rh_rs_std"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Relative Humidity number"; :unit = "1"; :comment = "Measured by radiosonde. Best product or final product L2 GDP GRUAN"; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :_ChunkSizes = 1U, 111U; // uint int wd_rs_nb(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "wd_rs, wd_rs_std"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Wind from direction number"; :unit = "1"; :comment = "In meteorological reports, the direction of the wind vector is usually (but not always) given as the direction from which it is blowing 57(wind_from_direction) (westerly, northerly, etc.). The direction is a bearing in the usual geographical sense, measured positive clockwise from due north."; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :_ChunkSizes = 1U, 111U; // uint int ws_rs_nb(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "ws_rs, ws_rs_std"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Horizontal wind speed number"; :unit = "1"; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :_ChunkSizes = 1U, 111U; // uint int u_rs_nb(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "u_rs, u_rs_std"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Eastward wind number"; :unit = "1"; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :_ChunkSizes = 1U, 111U; // uint int v_rs_nb(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "v_rs, v_rs_std"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Northward wind number"; :unit = "1"; :coverage_content_type = "physicalMeasurement"; :theme = "surface_meteorology"; :_ChunkSizes = 1U, 111U; // uint float ta_mwr(time=216206, altitude=111); :_FillValue = NaNf; // float :standard_name = "air_temperature"; :long_name = "Air temperature profile"; :units = "Celsius"; :cell_methods = "time:mean, altitude:mean"; :theme = "atmospheric_state"; :ancillary_variables = "ta_mwr_std, ta_mwr_nb"; :_ChunkSizes = 1U, 111U; // uint float ta_mwr_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "ta_mwr, ta_mwr_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Air temperature profile standard deviation"; :units = "inherit"; :theme = "atmospheric_state"; :_ChunkSizes = 1U, 111U; // uint int ta_mwr_nb(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "ta_mwr, ta_mwr_std"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Air temperature profile number"; :units = "1"; :theme = "atmospheric_state"; :_ChunkSizes = 1U, 111U; // uint float rh_mwr(time=216206, altitude=111); :_FillValue = NaNf; // float :standard_name = "relative_humidity"; :long_name = "Relative humidity profile"; :units = "%"; :cell_methods = "time:mean, altitude:mean"; :theme = "atmospheric_state"; :ancillary_variables = "rh_mwr_std, rh_mwr_nb"; :_ChunkSizes = 1U, 111U; // uint float rh_mwr_std(time=216206, altitude=111); :_FillValue = NaNf; // float :ancillary_variables = "rh_mwr, rh_mwr_nb"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Relative humidity profile standard deviation"; :units = "inherit"; :theme = "atmospheric_state"; :_ChunkSizes = 1U, 111U; // uint int rh_mwr_nb(time=216206, altitude=111); :_FillValue = -999; // int :ancillary_variables = "rh_mwr, rh_mwr_std"; :cell_methods = "time:mean, altitude:mean"; :long_name = "Relative humidity profile number"; :units = "1"; :theme = "atmospheric_state"; :_ChunkSizes = 1U, 111U; // uint String station_name; :standard_name = "platform_name"; :long_name = "station name"; :cf_role = "profile_id"; double station_lat; :_FillValue = NaN; // double :units = "degrees_north"; :standard_name = "latitude"; :axis = "Y"; :coverage_content_type = "coordinate"; double station_lon; :_FillValue = NaN; // double :units = "degrees_east"; :standard_name = "longitude"; :axis = "X"; :coverage_content_type = "coordinate"; double station_alt; :_FillValue = NaN; // double :units = "m"; :standard_name = "altitude"; :axis = "Z"; :coverage_content_type = "coordinate"; // global attributes: :title = "SIRTA 2D ReOBS dataset"; :summary = "The 20-year-long SIRTA-ReOBS dataset is contained in a single netCDF file containing mean values of more than 150 physical variables. Variables entering the ReOBS dataset are quality controlled at their native time resolution. The objective of ReObs is also to respect the FAIR principles (Findable, Accessible, Interoperable, Reusable) in particular the Reusable aspect which is more obvious for a production chain."; :keywords = "GCMD: ATMOSPHERE,GCMD: AEROSOLS,GCMD: AIR QUALITY,GCMD: ATMOSPHERIC PRESSURE,GCMD: LAND SURFACE/AGRICULTURE INDICATORS,GCMD: ATMOSPHERIC RADIATION,GCMD: ATMOSPHERIC TEMPERATURE,GCMD: ATMOSPHERIC WATER VAPOR,GCMD: ATMOSPHERIC WINDS,GCMD: CLOUDS,GCMD: PRECIPITATION,GCMD: DATA ANALYSIS AND VISUALIZATION,GCMD: CALIBRATION/VALIDATION,GCMD: DATA ANALYSIS,GCMD: STATISTICAL APPLICATIONS"; :keywords_vocabulary = "GCMD"; :Conventions = "CF-1.7, ACDD-1.3, ISO 8601"; :naming_authority = "AERIS data center"; :source = "AERIS data center,ACTRIS-FR,SIRTA,Meteo-France"; :comment = "Technical and scientific staff of SIRTA site discuss with AERIS data center staff to develop the quality check and provide the metadata information concerning variables and instruments."; :acknowledgement = "The ReOBS database is maintained by the French national center for Atmospheric data and services AERIS. We extend our acknowledgments to the technical and computer staff of SIRTA Observatory for taking the observations and making the data set easily accessible.We also thanks the ACTRIS-FR Research Infrastructure for their support in this study."; :license = "Inspired by CC-BY"; :standard_name_vocabulary = "CF Standard Name Table v76"; :creator_name = "AERIS data center"; :creator_type = "Data center"; :creator_url = "https://www.aeris-data.fr/"; :institution = "AERIS data center"; :project = "AERIS data center,ReOBS"; :program = "ACTRIS-FR"; :references = "https://doi.org/10.5194/essd-10-919-2018,https://doi.org/10.1002/2014GL060205,https://doi.org/10.1007/s00382-012-1469-y,https://hal.archives-ouvertes.fr/hal-00329353"; :publisher_name = "AERIS data center"; :publisher_type = "Institution"; :publisher_url = "https://www.aeris-data.fr/"; :processing_level = "See ATBD"; :metadata_link = "https://reobs.aeris-data.fr/"; :contributor_name = "AERIS data center,ACTRIS-FR,SIRTA,REOBS,Meteo-France"; :contributor_role = "AERIS is the data center, SIRTA is the observatory where all the instruments are installed, ACTRIS-FR is a research infrastructure where several algorithms are developed on different French sites, Meteo-France is the French met service to provide meteorological standard data in Paris area, ReOBS is the name of the AERIS project that coordinate the production chain and develop the quality control."; :instrument = "GCMD: In Situ/Laboratory Instruments,GCMD: Current/Wind Meters,GCMD: SONIC ANEMOMETER,GCMD: ANEMOMETERS,GCMD: EDDY CORRELATION DEVICES,GCMD: Gauges,GCMD: RAIN GAUGES,GCMD: Photon/Optical Detectors,GCMD: Pressure/Height Meters,GCMD: Probes,GCMD: SOIL MOISTURE PROBE,GCMD: TEMPERATURE PROBES,GCMD: Profilers/Sounders,GCMD: Radiation Sensors,GCMD: Temperature/Humidity Sensors,GCMD: Scatterometers,GCMD: Passive Remote Sensing,GCMD: Active Remote Sensing,GCMD: Photon/Optical Detectors,GCMD: Profilers/Sounders"; :time_coverage_start = "1998-07-23T23:00:00"; :time_coverage_end = "2023-04-05T23:00:00"; :time_coverage_duration = "P9022DT0H0M0S"; :time_coverage_resolution = "P0DT1H0M0S"; :created_date = "2023-04-06 22:31:05.486655"; :metadata_modified = "2023-04-06 22:31:05.486664"; :history = "Created on 2023-04-06T22:31:05.486671."; :uuid = "a1611d21-7df5-4afd-9d7f-f9aa24b7f15b"; :instrument_vocabulary = "GCMD"; :coordinates = "time_bnds altitude_bnds"; }