Merge pull request #4096 from nasa-gibs/release

Release 3.40.0 to Main

LICENSE.md

@@ -3,7 +3,7 @@
 This code was originally developed at NASA/Goddard Space Flight Center for
 the Earth Science Data and Information System (ESDIS) project.
 
-Copyright © 2013 - 2022 United States Government as represented by the
+Copyright © 2013 - 2023 United States Government as represented by the
 Administrator of the National Aeronautics and Space Administration.
 All Rights Reserved.
 
@@ -131,7 +131,7 @@ customarily used for software exchange.
 **B.** Each Recipient must ensure that the following copyright notice appears
 prominently in the Subject Software:
 
-    Copyright © 2012-2022 United States Government
+    Copyright © 2012-2023 United States Government
     as represented by the Administrator of the
     National Aeronautics and Space Administration.
     All Rights Reserved.

config/default/common/brand/about/license.md

@@ -1,5 +1,5 @@
 <h2>License</h2>
-<p>Copyright © 2013 - 2022 United States Government as represented by the Administrator of the National Aeronautics
+<p>Copyright © 2013 - 2023 United States Government as represented by the Administrator of the National Aeronautics
     and Space Administration. All Rights Reserved. This software is licensed under the <a
         href="https://ti.arc.nasa.gov/opensource/nosa/" target="_blank" rel="noopener noreferrer">NASA Open Source
         Software Agreement, Version 1.3</a>. Source code is available on the <a

config/default/common/config/metadata/layers/goes/GOES-West_ABI_Air_Mass.md

@@ -2,6 +2,6 @@ Note: This layer is generally available for the **most recent 90 days**, though
 
 The Air Mass layer from the GOES-West Advanced Baseline Imager (ABI) is used primarily for distinguishing between polar and tropical air masses, especially along frontal boundaries and identify high, mid, and low-level clouds. It can also be used to infer cyclogenesis by identifying warm, dry, ozone-rich descending stratospheric air associated with jet streams and potential vorticity (PV) anomalies. The RGB image is comprised of Bands 6.2-7.3, 9.6-10.4 and 6.2.
 
-The Geostationary Operational Environmental Satellites (GOES)-West satellite (currently, GOES-17) is centered on 137.2 degrees W, covering most of the Pacific Ocean, the USA, most of Canada, Central America, the western half of South America, and parts of Australasia. The GOES-West ABI imagery is available on a rolling 90-day basis at 10 minute intervals. The sensor resolution is 2 km, the imagery resolution in Worldview/Global Imagery Browse Services (GIBS) is 2 km, the temporal resolution is 10 minutes, and the latency (time from satellite acqusition to availability in GIBS) is approximately 40 minutes.
+The Geostationary Operational Environmental Satellites (GOES)-West satellite (currently, GOES-18) is centered on 137.2 degrees W, covering most of the Pacific Ocean, the USA, most of Canada, Central America, the western half of South America, and parts of Australasia. The GOES-West ABI imagery is available on a rolling 90-day basis at 10 minute intervals. The sensor resolution is 2 km, the imagery resolution in Worldview/Global Imagery Browse Services (GIBS) is 2 km, the temporal resolution is 10 minutes, and the latency (time from satellite acqusition to availability in GIBS) is approximately 40 minutes.
 
 References: [GOES-R: Air Mass RGB Quick Guide](https://nasasporttraining.files.wordpress.com/2015/12/quickguide_airmassrgb_nasa_sport.pdf)

config/default/common/config/metadata/layers/goes/GOES-West_ABI_Band13_Clean_Infrared.md

@@ -2,6 +2,6 @@ Note: This layer is generally available for the **most recent 90 days**, though
 
 The Clean Infrared (10.3 um, Band 13) layer from the GOES-West Advanced Baseline Imager (ABI) is useful for detecting clouds all times of day and night and is quite useful in retrievals of cloud top height. It is used to identify and classify cloud and other atmospheric features, estimate cloud-top brightness temperature and cloud particle size, convective severe weather signatures, and hurricane intensity. This infrared window is not strongly affected by atmospheric water vapor.
 
-The Geostationary Operational Environmental Satellites (GOES)-West satellite (currently, GOES-17) is centered on 137.2 degrees W, covering most of the Pacific Ocean, the USA, most of Canada, Central America, the western half of South America, and parts of Australasia. The GOES-West ABI imagery is available on a rolling 90-day basis at 10 minute intervals. The sensor resolution of Band 13 is 2 km, the imagery resolution in Worldview/Global Imagery Browse Services (GIBS) is 2 km, the temporal resolution is 10 minutes, and the latency (time from satellite acqusition to availability in GIBS) is approximately 40 minutes.
+The Geostationary Operational Environmental Satellites (GOES)-West satellite (currently, GOES-18) is centered on 137.2 degrees W, covering most of the Pacific Ocean, the USA, most of Canada, Central America, the western half of South America, and parts of Australasia. The GOES-West ABI imagery is available on a rolling 90-day basis at 10 minute intervals. The sensor resolution of Band 13 is 2 km, the imagery resolution in Worldview/Global Imagery Browse Services (GIBS) is 2 km, the temporal resolution is 10 minutes, and the latency (time from satellite acqusition to availability in GIBS) is approximately 40 minutes.
 
 References: [GOES-R: ABI Band 13 (10.3 um) Quick Guide](https://www.star.nesdis.noaa.gov/GOES/documents/ABIQuickGuide_Band13.pdf)

config/default/common/config/metadata/layers/goes/GOES-West_ABI_Band2_Red_Visible_1km.md

@@ -2,6 +2,6 @@ Note: This layer is generally available for the **most recent 90 days**, though
 
 The Red Visible (0.64 um, Band 2) layer from the GOES-West Advanced Baseline Imager (ABI) is used primarily to monitor the evolution of clouds throughout the daylight hours. It is also useful for identifying small-scale features such as river fog/clear air boundaries, or overshooting tops of cumulus clouds. It can also be used to identify daytime snow and ice cover, diagnose low-level cloud-drift winds, assist with detections of volcanic ash and analysis of hurricanes and winter storms.
 
-The Geostationary Operational Environmental Satellites (GOES)-West satellite (currently, GOES-17) is centered on 137.2 degrees W, covering most of the Pacific Ocean, the USA, most of Canada, Central America, the western half of South America, and parts of Australasia. The GOES-West ABI imagery is available on a rolling 90-day basis at 10 minute intervals. The sensor resolution of Band 2 is 0.5 km, the imagery resolution in Worldview/Global Imagery Browse Services (GIBS) is 1 km, the temporal resolution is 10 minutes,  and the latency (time from satellite acqusition to availability in GIBS) is approximtely 40 minutes.
+The Geostationary Operational Environmental Satellites (GOES)-West satellite (currently, GOES-18) is centered on 137.2 degrees W, covering most of the Pacific Ocean, the USA, most of Canada, Central America, the western half of South America, and parts of Australasia. The GOES-West ABI imagery is available on a rolling 90-day basis at 10 minute intervals. The sensor resolution of Band 2 is 0.5 km, the imagery resolution in Worldview/Global Imagery Browse Services (GIBS) is 1 km, the temporal resolution is 10 minutes,  and the latency (time from satellite acqusition to availability in GIBS) is approximtely 40 minutes.
 
 References: [GOES-R: ABI Band 2 (0.64 um) Quick Guide](https://www.star.nesdis.noaa.gov/GOES/documents/ABIQuickGuide_Band02.pdf)

config/default/common/config/metadata/layers/goes/GOES-West_ABI_GeoColor.md

@@ -2,7 +2,7 @@ Note: This layer is generally available for the **most recent 90 days**, though
 
 The GeoColor (True Color (Day), Multispectral blended infrared (IR; at Night)) layer from the GOES-West Advanced Baseline Imager (ABI) provides an approximation to daytime True Color imagery. The combination of spectral bands yields an appearance similar to what the human eye would perceive for land surface, oceanic and atmospheric features, with atmospheric correction used to make the appearance of these features sharper. Thus it is used primarily for the intuitive interpretation of meteorological and surface-based features such as smoke, blowing dust, and vegetation types (forests, deserts, croplands, etc.). At night, the true color imagery gives way to IR-based blended multispectral imagery that provides differentiation between low liquid water clouds (shown in light blue) and higher ice clouds (shown in gray/white). It also includes a static city lights/night lights database derived from the VIIRS Day/Night Band, which aids in geo-referencing and can help determine the proximity of clouds (such as fog) or weather hazards (such as thunderstorms or tropical cyclones) to population centers.  Please note that as these lights are static, they will not change even if, for example, a weather-induced power outage occurs.
 
-The Geostationary Operational Environmental Satellites (GOES)-West satellite (currently, GOES-17) is centered on 137.2 degrees W, covering most of the Pacific Ocean, the USA, most of Canada, Central America, the western half of South America, and parts of Australasia. The GOES-West ABI imagery is available on a rolling 90-day basis at 10 minute intervals. The product resolution is 1 km, the imagery resolution in Worldview/Global Imagery Browse Services (GIBS) is 1 km, the temporal resolution is 10 minutes, and the latency (time from satellite acqusition to availability in GIBS) is approximately 40 minutes.
+The Geostationary Operational Environmental Satellites (GOES)-West satellite (currently, GOES-18) is centered on 137.2 degrees W, covering most of the Pacific Ocean, the USA, most of Canada, Central America, the western half of South America, and parts of Australasia. The GOES-West ABI imagery is available on a rolling 90-day basis at 10 minute intervals. The product resolution is 1 km, the imagery resolution in Worldview/Global Imagery Browse Services (GIBS) is 1 km, the temporal resolution is 10 minutes, and the latency (time from satellite acqusition to availability in GIBS) is approximately 40 minutes.
 
 GeoColor Imagery provided by [NOAA/NESDIS/STAR](https://www.star.nesdis.noaa.gov/goes/).
 

config/default/common/config/metadata/layers/viirs/VIIRS_NOAA20_CorrectedReflectance_BandsM11-I2-I1_Granule.md

@@ -1,3 +1,5 @@
+**NOTE: This layer is undergoing beta testing. Imagery is pixelated in certain areas and is currently being investigated.**
+
 Granule Corrected Reflectance imagery displays each 6-minute granule of imagery in near real-time. It is available on a 15 day rolling window basis. Each granule shows imagery as it was captured by the VIIRS instrument in that 6-minute time period and reveals areas that may have otherwise been obscured by the mosaicking of subsequent overpasses.
 
 For a daily overview, please refer to the associated Corrected Reflectance Mosaic/Composite image.

config/default/common/config/metadata/layers/viirs/VIIRS_NOAA20_CorrectedReflectance_BandsM3-I3-M11_Granule.md

@@ -1,3 +1,5 @@
+**NOTE: This layer is undergoing beta testing. Imagery is pixelated in certain areas and is currently being investigated.**
+
 Granule Corrected Reflectance imagery displays each 6-minute granule of imagery in near real-time. It is available on a 15 day rolling window basis. Each granule shows imagery as it was captured by the VIIRS instrument in that 6-minute time period and reveals areas that may have otherwise been obscured by the mosaicking of subsequent overpasses.
 
 For a daily overview, please refer to the associated Corrected Reflectance Mosaic/Composite image.

config/default/common/config/metadata/layers/viirs/VIIRS_NOAA20_CorrectedReflectance_TrueColor_Granule.md

@@ -1,3 +1,5 @@
+**NOTE: This layer is undergoing beta testing. Imagery is pixelated in certain areas and is currently being investigated.**
+
 Granule Corrected Reflectance imagery displays each 6-minute granule of imagery in near real-time. It is available on a 15 day rolling window basis. Each granule shows imagery as it was captured by the VIIRS instrument in that 6-minute time period and reveals areas that may have otherwise been obscured by the mosaicking of subsequent overpasses.
 
 For a daily overview, please refer to the associated Corrected Reflectance Mosaic/Composite image.

config/default/common/config/metadata/layers/viirs/VIIRS_SNPP_CorrectedReflectance_BandsM11-I2-I1_Granule.md

@@ -1,3 +1,5 @@
+**NOTE: This layer is undergoing beta testing. Imagery is pixelated in certain areas and is currently being investigated.**
+
 Granule Corrected Reflectance imagery displays each 6-minute granule of imagery in near real-time. It is available on a 15 day rolling window basis. Each granule shows imagery as it was captured by the VIIRS instrument in that 6-minute time period and reveals areas that may have otherwise been obscured by the mosaicking of subsequent overpasses.
 
 For a daily overview, please refer to the associated Corrected Reflectance Mosaic/Composite image.

config/default/common/config/metadata/layers/viirs/VIIRS_SNPP_CorrectedReflectance_BandsM3-I3-M11_Granule.md

@@ -1,3 +1,4 @@
+**NOTE: This layer is undergoing beta testing. Imagery is pixelated in certain areas and is currently being investigated.**
 
 Granule Corrected Reflectance imagery displays each 6-minute granule of imagery in near real-time. It is available on a 15 day rolling window basis. Each granule shows imagery as it was captured by the VIIRS instrument in that 6-minute time period and reveals areas that may have otherwise been obscured by the mosaicking of subsequent overpasses.
 

config/default/common/config/metadata/layers/viirs/VIIRS_SNPP_CorrectedReflectance_TrueColor_Granule.md

@@ -1,3 +1,5 @@
+**NOTE: This layer is undergoing beta testing. Imagery is pixelated in certain areas and is currently being investigated.**
+
 Granule Corrected Reflectance imagery displays each 6-minute granule of imagery in near real-time. It is available on a 15 day rolling window basis. Each granule shows imagery as it was captured by the VIIRS instrument in that 6-minute time period and reveals areas that may have otherwise been obscured by the mosaicking of subsequent overpasses.
 
 For a daily overview, please refer to the associated Corrected Reflectance Mosaic/Composite image.

config/default/common/config/metadata/stories/geostationary/step004.md

@@ -1 +1 @@
-The Geostationary Operational Environmental Satellites (GOES)-West satellite (currently, GOES-S/GOES-17) is centered on 137.2 degrees West, covering most of the Pacific Ocean, the USA, most of Canada, Central America, the western half of South America, and parts of Australasia.
+The Geostationary Operational Environmental Satellites (GOES)-West satellite (currently, GOES-T/GOES-18) is centered on 137.2 degrees West, covering most of the Pacific Ocean, the USA, most of Canada, Central America, the western half of South America, and parts of Australasia.

config/default/common/config/metadata/stories/hurricane_dorian_september_2019/step001.md

@@ -1,6 +1,6 @@
 This true color Corrected Reflectance image shows Hurricane Dorian over the Bahamas, taken at approximately 18:35 UTC on 1 September 2019. The image was captured by the Visible Infrared Imaging Radiometer Suite (VIIRS) instrument on the joint NASA/NOAA Suomi National Polar-orbiting Partnership (Suomi NPP) satellite.
 
-Worldview has been consistently providing daily, global satellite imagery from polar orbiting satellites like the joint NASA/NOAA Suomi NPP, but Worldview is moving into new territory - supplying satellite imagery every 10 minutes from geostationary satellites like GOES-East (currently, GOES-R/GOES-16), GOES-West (currently, GOES-S/GOES-17) and Himawari-8!
+Worldview has been consistently providing daily, global satellite imagery from polar orbiting satellites like the joint NASA/NOAA Suomi NPP, but Worldview is moving into new territory - supplying satellite imagery every 10 minutes from geostationary satellites like GOES-East (currently, GOES-R/GOES-16), GOES-West (currently, GOES-T/GOES-18) and Himawari-8!
 
 ***
 - [GOES-R](https://www.goes-r.gov/)

config/default/common/config/metadata/stories/hurricane_dorian_september_joyride/step001.md

@@ -1,6 +1,6 @@
 This true color Corrected Reflectance image shows Hurricane Dorian over the Bahamas, taken at approximately 18:35 UTC on 1 September 2019. The image was captured by the Visible Infrared Imaging Radiometer Suite (VIIRS) instrument on the joint NASA/NOAA Suomi National Polar-orbiting Partnership (Suomi NPP) satellite.
 
-Worldview has been consistently providing daily, global satellite imagery from polar orbiting satellites like the joint NASA/NOAA Suomi NPP, but Worldview is moving into new territory - supplying satellite imagery every 10 minutes from geostationary satellites like GOES-East (currently, GOES-R/GOES-16), GOES-West (currently, GOES-S/GOES-17) and Himawari-8!
+Worldview has been consistently providing daily, global satellite imagery from polar orbiting satellites like the joint NASA/NOAA Suomi NPP, but Worldview is moving into new territory - supplying satellite imagery every 10 minutes from geostationary satellites like GOES-East (currently, GOES-R/GOES-16), GOES-West (currently, GOES-T/GOES-18) and Himawari-8!
 
 ***
 - [GOES-R](https://www.goes-r.gov/)