Using the Multisensor Advected Layered Precipitable Water Product in the Operational Forecast Environment

Gitro, Christopher M.; Nws, Kansas City; Hill, Missouri Pleasant; Jurewicz, Michael L.; Kusselson, Sheldon J.; Forsythe, J. M.; Kidder, Stanley Q.; Szoke, Edward J.; Bikos, Dan; Jones, Andrew S.; Gravelle, Chad M.; Grassotti, Christopher

doi:10.15191/nwajom.2018.0606

Cited by 8 publications

(3 citation statements)

References 29 publications

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“…Discussions in theme 4 highlighted the significance of satellite-based precipitation and water vapor products in enhancing weather forecasting and societal applications over challenging terrains like Alaska. The value of various LEO precipitation products for forecasters was emphasized, including the Advected Layer Precipitable Water (ALPW; Gitro et al 2018) product, which provides insights into atmospheric water vapor distribution. The insights from the National Weather Service (NWS) Weather Forecast Offices (WFOs) and Weather Prediction Center (WPC) shed light on the critical role of low-latency precipitation products in situational awareness and short-term forecasting.…”

Section: Precipitation Estimation Users and Applicationsmentioning

confidence: 99%

Advances in Precipitation Retrieval and Applications from Low-Earth-Orbiting Satellite Information

Afzali Gorooh,

Hsu,

Ferraro

et al. 2023

Bulletin of the American Meteorological Society

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Section: Precipitation Estimation Users and Applicationsmentioning

confidence: 99%

Advances in Precipitation Retrieval and Applications from Low-Earth-Orbiting Satellite Information

Afzali Gorooh,

Hsu,

Ferraro

et al. 2023

Bulletin of the American Meteorological Society

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“…Satellites used in the initial LPW study were S-NPP, NOAA-19/20, MetOp-A/B, and Defense Meteorological Satellite Program F17/18. Advection of retrieved LPW utilizes winds from the Finite Volume Cubed Global Forecast System (FV3GFS, hereafter GFS) to create Advected Layer Precipitable Water (ALPW), which uses a technique called advective blending (Gitro et al, 2018). ALPW is computed within the following four pressure layers: (1) the surface to 850 hPa, (2) 850-700 hPa, (3) 700-500 hPa, and (4) 500-300 hPa.…”

Section: Satellite Datamentioning

confidence: 99%

Satellite imagery and products of the 16–17 February 2020 Saharan Air Layer dust event over the eastern Atlantic: impacts of water vapor on dust detection and morphology

et al. 2021

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Abstract. On 16–17 February 2020, dust within the Saharan Air Layer (SAL) from western Africa moved over the eastern Atlantic Ocean. Satellite imagery and products from the ABI on GOES-16, VIIRS on NOAA-20, and CALIOP on CALIPSO, along with retrieved values of layer and total precipitable water (TPW) from MIRS and NUCAPS, respectively, were used to identify dust within the SAL over the eastern Atlantic Ocean. Various satellite imagery and products were also used to characterize the distribution of water vapor within the SAL. There was a distinct pattern between dust detection and dust masking and values of precipitable water. Specifically, dust was detected when values of layer TPW were approximately 14 mm; in addition, dust was masked when values of layer TPW were approximately 28 mm. In other words, water vapor masked infrared dust detection if sufficient amounts of water vapor existed in a column. Results herein provide observational support to two recent numerical studies that concluded water vapor can mask infrared detection of airborne dust.

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“…Several examples of IDSS activities have been documented in the literature. Lindley et al (2016) demonstrated the utility of using text-and graphical-based communication strategies to alert fire weather partners of satellite-detected fire ignitions, which resulted in a more rapid and efficient response to emerging wildfire threats. IDSS has also been employed during severe weather events.…”

Section: Nwa Journal Of Operational Meteorologymentioning

confidence: 99%

Cool Season Small Hail over the West Coast of the United States: Environments, Hazards, and Decision Support

Garner

Iwasko

Kidwell

et al. 2019

J. Operational Meteor.

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National Weather Service (NWS) forecasters across the west coast of the United States often deal with cool season hail showers that produce hazardous driving conditions. These small hail events, with diameters averaging 5.8 mm, occur with cold upper troughs that support weak instability favorable for low-topped convection and reflectivity values averaging 48 dBZ. The public generally assumes that heavy snow is common across west coast mountains, while heavy rain prevails near sea level. However, motorists can be caught offguard when wet, relatively warm low elevation roadways suddenly transition to icy hail-covered conditions. Thus, west coast small hail events represent an opportunity for the NWS to provide tailored messaging that can modify public perceptions and optimize outcomes. This research examines environments supportive of accumulating small hail over the western United States during the period 2008–2018, and supplements the environmental analysis with a summary of enhanced impact-based decision support techniques used to alert NWS partners and the general public.

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Using the Multisensor Advected Layered Precipitable Water Product in the Operational Forecast Environment

Cited by 8 publications

References 29 publications

Advances in Precipitation Retrieval and Applications from Low-Earth-Orbiting Satellite Information

Advances in Precipitation Retrieval and Applications from Low-Earth-Orbiting Satellite Information

Satellite imagery and products of the 16–17 February 2020 Saharan Air Layer dust event over the eastern Atlantic: impacts of water vapor on dust detection and morphology

Cool Season Small Hail over the West Coast of the United States: Environments, Hazards, and Decision Support

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