CLDPROP_L2_VIIRS_SNPP - VIIRS/SNPP Cloud Properties L2 6-Min Swath 750 m
The Suomi National Polar-orbiting Partnership (SNPP) Visible Infrared Imaging Radiometer Suite (VIIRS) NASA Level-2 (L2) Cloud Properties is one of two continuity products designed to sustain the long-term records of both Moderate Resolution Imaging Spectroradiometer (MODIS) and VIIRS heritages. CLDPROP_L2_VIIRS_SNPP is the shortname for the SNPP VIIRS incarnation of the Cloud Properties continuity product. This product ensures continuity of approach through a common algorithm that is applicable to both MODIS and VIIRS data.
The original MODIS cloud-top and cloud optical properties algorithms (MOD06 suite) benefit from their access, via the MODIS instrument, to thermal infrared absorption channels that provide information on cloud thermodynamic phase and cloud-top properties, including the 7.5 µm water vapor channel and several channels within the 13 µm CO2 absorption band that facilitate a CO2-slicing method to retrieve cloud-top pressure. Given the lack of such spectral channels in the VIIRS instrument, in addition to the spectral offset between the MODIS 2.13 µm and VIIRS 2.25 µm shortwave infrared (SWIR) channels in which ice and liquid cloud absorption differs, a direct porting of the original MODIS MOD35 and MOD06 algorithms to VIIRS is precluded. The commonly applicable CLDPROP algorithm provides a continuity of approach between MODIS and VIIRS, leveraging only those spectral channels that are common to both instruments. In the CLDPROP algorithm, cloud-top property retrievals are derived through NOAA’s operational algorithms developed for Advanced Very-High Resolution Radiometer (AVHRR), VIIRS, and Geostationary Operational Environmental Satellites (GOES)-16/17, specifically the Clouds from AVHRR Extended (CLAVR-x) processing system for cloud-top phase (algorithm based primarily on infrared spectral channels, with additional information from select SWIR channels) and NOAA’s Enterprise Algorithm Working Group (AWG) Cloud Height Algorithm (ACHA) for cloud-top properties. Besides a modified version of the SNPP VIIRS Level-1B (including restored bow-tie deleted pixels and radiometric adjustments to several shortwave channels to address known radiometric offsets between MODIS and VIIRs), this product uses the SNPP VIIRS CLDMSK continuity product, and several ancillary data inputs; they include gap-filled MODIS snow/ice surface spectral albedos, Near-real-time Ice and Snow Extent (NISE) inputs, and National Centers for Environmental Prediction (NCEP) Global Data Assimilation System (GDAS) forecast analysis fields. The nominal spatial resolution of the SNPP VIIRS L2 Cloud Properties product is 750 meters.
The L2 netCDF product, acquired and processed every 6 minutes, contains the following four data groups and Science Data Set (SDS) layers in each group:
Cloud model data:
- Ice particle asymmetry parameter
- Liquid water droplet asymmetry parameter
- Ice particle extinction efficiency
- Liquid water droplet extinction efficiency
- Ice particle single scattering albedo
- Liquid water droplet single scattering albedo
Geophysical data:
- Atmospherically corrected reflectance used during cloud optical and microphysical properties retrieval
- Cloud Effective Emissivity from NOAA CLAVR-x AWG algorithm at 11µm
- Cloud Particle Effective Radius two-channel retrieval using 2.2 µm and either 0.65 µm, 0.86 µm or 1.24 µm (specified in Quality_Assurance) from best points: not failed in any way, not marked for clear sky restoral
- Cloud Particle Effective Radius two-channel retrieval using 1.6 µm and either 0.65 µm, 0.86 µm or 1.24 µm (specified in Quality_Assurance) from best points: not failed in any way, not marked for clear sky restoral
- Cloud Particle Effective Radius two-channel retrieval using 2.2 µm and 1.6 µm from best points: not failed in any way, not marked for clear sky restoral
- Cloud Particle Effective Radius two-channel retrieval using 2.2 µm and 1.6 µm from points identified as partly cloudy from cloud edges
- Cloud Particle Effective Radius two-channel retrieval using 1.6 µm and either 0.65 µm, 0.86 µm or 1.24 µm (specified in Quality_Assurance) from points identified as partly cloudy from cloud edges
- Cloud Particle Effective Radius two-channel retrieval using 3.7 µm and either 0.65 µm, 0.86 µm or 1.24 µm (specified in Quality_Assurance) from best points: not failed in any way, not marked for clear sky restoral
- Cloud Particle Effective Radius two-channel retrieval using 3.7 µm and either 0.65 µm, 0.86 µm or 1.24 µm (specified in Quality_Assurance) from points identified as partly cloudy from cloud edges
- Cloud Particle Effective Radius two-channel retrieval using 2.2 µm and either 0.65 µm, 0.86 µm or 1.24 µm (specified in Quality_Assurance) from points identified as partly cloudy from cloud edges
- Cloud Effective Particle Radius from 2.2 µm Relative Uncertainty (Percent) from both best points and points identified as cloud edge
- Cloud Effective Particle Radius from 1.6 µm Relative Uncertainty (Percent) from both best points and points identified as cloud edge
- Cloud Effective Particle Radius Relative Uncertainty (Percent) using 2.2 µm and 1.6 µm from both best points and points identified as cloud edge
- Cloud Effective Particle Radius from 3.7 µm Relative Uncertainty (Percent) from both best points and points identified as cloud edge
- 3-d byte array from which cloud mask information can be extracted
- Cloud Optical Thickness two-channel retrieval using 2.2 µm and either 0.65 µm, 0.86 µm or 1.24 µm (specified in Quality_Assurance) from best points: not failed in any way, not marked for clear sky restoral
- Cloud Optical Thickness two-channel retrieval using 1.6 µm and either 0.65 µm, 0.86 µm or 1.24 µm (specified in Quality_Assurance) from best points: not failed in any way, not marked for clear sky restoral
- Cloud Optical Thickness two-channel retrieval using 2.2 µm and 1.6 µm from best points: not failed in any way, not marked for clear sky restoral
- Cloud Optical Thickness two-channel retrieval using 2.2 µm and 1.6 µm from points identified as partly cloudy from cloud edges
- Cloud Optical Thickness two-channel retrieval using 1.6 µm and either 0.65 µm, 0.86 µm or 1.24 µm (specified in Quality_Assurance) from points identified as partly cloudy from cloud edges
- Cloud Optical Thickness two-channel retrieval using 3.7 µm and either 0.65 µm, 0.86 µm or 1.24 µm (specified in Quality_Assurance) from best points: not failed in any way, not marked for clear sky restoral
- Cloud Optical Thickness two-channel retrieval using 3.7 µm and either 0.65 µm, 0.86 µm or 1.24 µm (specified in Quality_Assurance) from points identified as partly cloudy from cloud edges
- Cloud Optical Thickness two-channel retrieval using 2.2 µm and either 0.65 µm, 0.86 µm or 1.24 µm (specified in Quality_Assurance) from points identified as partly cloudy from cloud edges
- Cloud Optical Thickness from 2.2 µm Relative Uncertainty (Percent) from both best points and points identified as cloud edge
- Cloud Optical Thickness from 1.6 µm Relative Uncertainty (Percent) from both best points and points identified as cloud edge
- Cloud Optical Thickness Relative Uncertainty (Percent) using 2.2 µm and 1.6 µm from both best points and points identified as cloud edge
- Cloud Optical Thickness from 3.7 µm Relative Uncertainty (Percent) from both best points and points identified as cloud edge
- Cloud Phase Determination from NOAA CLAVR-x AWG algorithm
- Cloud Phase Determination Used in Optical Thickness/Effective Radius Retrieval
- Cloud Top Height from NOAA CLAVR-x AWG algorithm
- Cloud Top Height uncertainty from NOAA CLAVR-x AWG algorithm
- Cloud Top Pressure from NOAA CLAVR-x AWG algorithm
- Cloud Top Pressure uncertainty from NOAA CLAVR-x AWG algorithm
- Cloud Top Temperature from NOAA CLAVR-x AWG algorithm
- Cloud Top Temperature uncertainty from NOAA CLAVR-x AWG algorithm
- Column Water Path two-channel retrieval using 2.2 µm and either 0.65 µm, 0.86 µm or 1.24 µm (specified in Quality_Assurance) from best points: not failed in any way, not marked for clear sky restoral
- Column Water Path two-channel retrieval using 1.6 µm and either 0.65 µm, 0.86 µm or 1.24 µm (specified in Quality_Assurance) from best points: not failed in any way, not marked for clear sky restoral
- Column Water Path two-channel retrieval using 2.2 µm and 1.6 µm from best points: not failed in any way, not marked for clear sky restoral
- Column Water Path two-channel retrieval using 2.2 µm and 1.6 µm from points identified as partly cloudy from cloud edges
- Column Water Path two-channel retrieval using 1.6 µm and either 0.65 µm, 0.86 µm or 1.24 µm (specified in Quality_Assurance) from points identified as partly cloudy from cloud edges
- Column Water Path two-channel retrieval using 3.7 µm and either 0.65 µm, 0.86 µm or 1.24 µm (specified in Quality_Assurance) from best points: not failed in any way, not marked for clear sky restoral
- Column Water Path two-channel retrieval using 3.7 µm and either 0.65 µm, 0.86 µm or 1.24 µm (specified in Quality_Assurance) from points identified as partly cloudy from cloud edges
- Column Water Path two-channel retrieval using 2.2 µm and either 0.65 µm, 0.86 µm or 1.24 µm (specified in Quality_Assurance) from points identified as partly cloudy from cloud edges
- Cloud Water Path from 2.2 µm Relative Uncertainty (Percent) from both best points and points identified as cloud edge
- Cloud Water Path from 1.6 µm Relative Uncertainty (Percent) from both best points and points identified as cloud edge
- Cloud Water Path Relative Uncertainty (Percent) using 2.2 µm and 1.6 µm from both best points and points identified as cloud edge
- Cloud Water Path from 3.7 µm Relative Uncertainty (Percent) from both best points and points identified as cloud edge
- Low Cloud Temperature from IR Window retrieval using cloud emissivity based on cloud optical thickness
- 3-D byte array from which much info about quality (QA) of retrieval data can be extracted
- Retrievals and other information for points that failed to retrieve via standard solution logic for retrieval using 2.2 µm and either 0.65 µm, 0.86 µm or 1.2 µm (specified in Quality_Assurance)
- Retrievals and other information for points that failed to retrieve via standard solution logic for retrieval using 1.6 µm and either 0.65 µm, 0.86 µm or 1.2 µm (specified in Quality_Assurance)
- Retrievals and other information for points that failed to retrieve via standard solution logic for retrieval using 2.2 µm and 1.6 µm
- Retrievals and other information for points that failed to retrieve via standard solution logic for retrieval using 3.7 µm and either 0.65 µm, 0.86 µm or 1.2 µm (specified in Quality_Assurance)
- Surface pressure from ancillary data
Geolocation data:
- Latitude from instrument geolocation
- Longitude from instrument geolocation
- Sensor Azimuth Angle, Cell to Sensor
- Sensor Zenith Angle, Cell to Sensor
- Solar Azimuth Angle, Cell to Sun
- Solar Zenith Angle, Cell to Sun
Scanline attributes: 1. Scan start time (TAI93)
Consult the EOS MODIS and SNPP VIIRS Cloud Properties product user guide for additional information regarding the SNPP VIIRS CLDPROP product and its variables, its algorithm, output file, file naming conventions, and quality flags. Users are also encouraged to consult the User Guide and ATBD for the original MODIS version of the Cloud Top/Optical Properties product, referenced in the links below, to understand this product’s heritage.
Links
- Search for Product Files
- Data Archive
- MODIS Cloud Top Properties and Cloud Phase Algorithm Theoretical Basis Document
- Cloud Retrieval Algorithms for MODIS: Optical Thickness, Effective Particle Radius, and Thermodynamic Phase
- MODIS Atmosphere QA Plan for Collection 006
- EOS MODIS and SNPP VIIRS Cloud Properties: User Guide for the Climate Data Record Continuity Level-2 Cloud Top and Optical Properties Product (CLDPROP)
- VIIRS Collection 1 Continuity VIIRS File Specification
- DOI: 10.5067/VIIRS/CLDPROP_L2_VIIRS_SNPP.011
Shortname: | CLDPROP_L2_VIIRS_SNPP |
Platform: | Suomi-NPP |
Instrument: | VIIRS |
Processing Level: | Level-2 |
Spatial Resolution: | 750 m |
Temporal Resolution: | 6 minute |
ArchiveSets: | 5111 |
Collection: | NPP VIIRS Atmosphere data 1.1.0 (UWisc) (ArchiveSet 5111) |
PGE Number: | NONE |
File Naming Convention: | CLDPROP_L2_VIIRS_SNPP.AYYYYDDD.HHMM.CCC.YYYYDDDHHMMSS.nc |
Citation: | Platnick, S., et al., 2017. VIIRS Atmosphere L2 Cloud Properties Product. Version-1. NASA Level-1 and Atmosphere Archive & Distribution System (LAADS) Distributed Active Archive Center (DAAC), Goddard Space Flight Center, USA: http://dx.doi.org/10.5067/VIIRS/CLDPROP_L2_VIIRS_SNPP.001 |
Keywords: | SNPP VIIRS, L2 Swath, 6-Minute, Cloud Top Properties, Optical Properties, Microphysical Properties |