Doppler-Lidar Evaluation of HRRR-Model Skill at Simulating Summertime Wind Regimes in the Columbia River Basin during WFIP2
Complex-terrain locations often have repeatable near-surface wind patterns, such as synoptic gap flows and local thermally forced flows. An example is the Columbia River Valley in east-central Oregon-Washington, a significant wind-energy-generation region and the site of the Second Wind-Forecast Imp...
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| Veröffentlicht in: | Weather and forecasting 2021-12, Vol.36 (6), p.1961 |
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| creator | Banta, Robert M. Pichugina, Yelena L. Darby, Lisa S. Brewer, W. Alan Olson, Joseph B. Kenyon, Jaymes S. Baidar, S. Benjamin, S.G. Fernando, H.J.S. Lantz, K.O. Lundquist, J.K. McCarty, B.J. Marke, T. Sandberg, S.P. Sharp, J. Shaw, W.J. Turner, D.D. Wilczak, J.M. Worsnop, R. Stoelinga, M.T. |
| description | Complex-terrain locations often have repeatable near-surface wind patterns, such as synoptic gap flows and local thermally forced flows. An example is the Columbia River Valley in east-central Oregon-Washington, a significant wind-energy-generation region and the site of the Second Wind-Forecast Improvement Project (WFIP2). Data from three Doppler lidars deployed during WFIP2 define and characterize summertime wind regimes and their large-scale contexts, and provide insight into NWP model errors by examining differences in the ability of a model [NOAA’s High-Resolution Rapid-Refresh (HRRR-version1)] to forecast wind-speed profiles for different regimes. Seven regimes were identified based on daily time series of the lidar-measured rotor-layer winds, which then suggested two broad categories. First, in three regimes the primary dynamic forcing was the large-scale pressure gradient. Second, in two regimes the dominant forcing was the diurnal heating-cooling cycle (regional sea-breeze-type dynamics), including the
marine intrusion
previously described, which generates strong nocturnal winds over the region. The other two included a hybrid regime and a non-conforming regime. For the large-scale pressure-gradient regimes, HRRR had wind-speed biases of ~1 m s
−1
and RMSEs of 2-3 m s
−1
. Errors were much larger for the thermally forced regimes, owing to the premature demise of the strong nocturnal flow in HRRR. Thus, the more dominant the role of surface heating in generating the flow, the larger the errors. Major errors could result from surface heating of the atmosphere, boundary-layer responses to that heating, and associated terrain interactions. Measurement/modeling research programs should be aimed at determining which modeled processes produce the largest errors, so those processes can be improved and errors reduced. |
| doi_str_mv | 10.1175/WAF-D-21-0012.1 |
| format | Article |
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marine intrusion
previously described, which generates strong nocturnal winds over the region. The other two included a hybrid regime and a non-conforming regime. For the large-scale pressure-gradient regimes, HRRR had wind-speed biases of ~1 m s
−1
and RMSEs of 2-3 m s
−1
. Errors were much larger for the thermally forced regimes, owing to the premature demise of the strong nocturnal flow in HRRR. Thus, the more dominant the role of surface heating in generating the flow, the larger the errors. Major errors could result from surface heating of the atmosphere, boundary-layer responses to that heating, and associated terrain interactions. Measurement/modeling research programs should be aimed at determining which modeled processes produce the largest errors, so those processes can be improved and errors reduced.</description><identifier>ISSN: 0882-8156</identifier><identifier>EISSN: 1520-0434</identifier><identifier>DOI: 10.1175/WAF-D-21-0012.1</identifier><language>eng</language><publisher>Boston: American Meteorological Society</publisher><subject>Atmospheric boundary layer ; Atmospheric models ; Boundary layers ; Doppler lidar ; Doppler sonar ; Errors ; Forecast improvement ; Heating ; Lidar ; Mathematical models ; Modelling ; Nocturnal ; Pressure gradients ; Research programs ; River basins ; River valleys ; Rivers ; Sea breezes ; Surface wind ; Terrain ; weather ; weather model ; weather prediction ; Wind ; WIND ENERGY ; Wind power ; Wind profiles ; Wind speed ; Winds</subject><ispartof>Weather and forecasting, 2021-12, Vol.36 (6), p.1961</ispartof><rights>Copyright American Meteorological Society Dec 2021</rights><lds50>peer_reviewed</lds50><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c296t-f808cc7928a07ebf3193dc1852176e27862c38d4c4e74f6e3813a7c5db8454b23</citedby><cites>FETCH-LOGICAL-c296t-f808cc7928a07ebf3193dc1852176e27862c38d4c4e74f6e3813a7c5db8454b23</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>230,314,780,784,885,3681,27924,27925</link.rule.ids><backlink>$$Uhttps://www.osti.gov/servlets/purl/1825877$$D View this record in Osti.gov$$Hfree_for_read</backlink></links><search><creatorcontrib>Banta, Robert M.</creatorcontrib><creatorcontrib>Pichugina, Yelena L.</creatorcontrib><creatorcontrib>Darby, Lisa S.</creatorcontrib><creatorcontrib>Brewer, W. Alan</creatorcontrib><creatorcontrib>Olson, Joseph B.</creatorcontrib><creatorcontrib>Kenyon, Jaymes S.</creatorcontrib><creatorcontrib>Baidar, S.</creatorcontrib><creatorcontrib>Benjamin, S.G.</creatorcontrib><creatorcontrib>Fernando, H.J.S.</creatorcontrib><creatorcontrib>Lantz, K.O.</creatorcontrib><creatorcontrib>Lundquist, J.K.</creatorcontrib><creatorcontrib>McCarty, B.J.</creatorcontrib><creatorcontrib>Marke, T.</creatorcontrib><creatorcontrib>Sandberg, S.P.</creatorcontrib><creatorcontrib>Sharp, J.</creatorcontrib><creatorcontrib>Shaw, W.J.</creatorcontrib><creatorcontrib>Turner, D.D.</creatorcontrib><creatorcontrib>Wilczak, J.M.</creatorcontrib><creatorcontrib>Worsnop, R.</creatorcontrib><creatorcontrib>Stoelinga, M.T.</creatorcontrib><creatorcontrib>National Renewable Energy Lab. (NREL), Golden, CO (United States)</creatorcontrib><title>Doppler-Lidar Evaluation of HRRR-Model Skill at Simulating Summertime Wind Regimes in the Columbia River Basin during WFIP2</title><title>Weather and forecasting</title><description>Complex-terrain locations often have repeatable near-surface wind patterns, such as synoptic gap flows and local thermally forced flows. An example is the Columbia River Valley in east-central Oregon-Washington, a significant wind-energy-generation region and the site of the Second Wind-Forecast Improvement Project (WFIP2). Data from three Doppler lidars deployed during WFIP2 define and characterize summertime wind regimes and their large-scale contexts, and provide insight into NWP model errors by examining differences in the ability of a model [NOAA’s High-Resolution Rapid-Refresh (HRRR-version1)] to forecast wind-speed profiles for different regimes. Seven regimes were identified based on daily time series of the lidar-measured rotor-layer winds, which then suggested two broad categories. First, in three regimes the primary dynamic forcing was the large-scale pressure gradient. Second, in two regimes the dominant forcing was the diurnal heating-cooling cycle (regional sea-breeze-type dynamics), including the
marine intrusion
previously described, which generates strong nocturnal winds over the region. The other two included a hybrid regime and a non-conforming regime. For the large-scale pressure-gradient regimes, HRRR had wind-speed biases of ~1 m s
−1
and RMSEs of 2-3 m s
−1
. Errors were much larger for the thermally forced regimes, owing to the premature demise of the strong nocturnal flow in HRRR. Thus, the more dominant the role of surface heating in generating the flow, the larger the errors. Major errors could result from surface heating of the atmosphere, boundary-layer responses to that heating, and associated terrain interactions. Measurement/modeling research programs should be aimed at determining which modeled processes produce the largest errors, so those processes can be improved and errors reduced.</description><subject>Atmospheric boundary layer</subject><subject>Atmospheric models</subject><subject>Boundary layers</subject><subject>Doppler lidar</subject><subject>Doppler sonar</subject><subject>Errors</subject><subject>Forecast improvement</subject><subject>Heating</subject><subject>Lidar</subject><subject>Mathematical models</subject><subject>Modelling</subject><subject>Nocturnal</subject><subject>Pressure gradients</subject><subject>Research programs</subject><subject>River basins</subject><subject>River valleys</subject><subject>Rivers</subject><subject>Sea breezes</subject><subject>Surface wind</subject><subject>Terrain</subject><subject>weather</subject><subject>weather model</subject><subject>weather prediction</subject><subject>Wind</subject><subject>WIND ENERGY</subject><subject>Wind power</subject><subject>Wind profiles</subject><subject>Wind speed</subject><subject>Winds</subject><issn>0882-8156</issn><issn>1520-0434</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2021</creationdate><recordtype>article</recordtype><recordid>eNotkU1P4zAQhq3VItGFPXO1lrPBM_mwc4SWAlIRKGXVo-U6DhiSuNgOEto_v6nKaUaaZ1690kPIGfALAFFcbq6WbMEQGOeAF_CDzKBAznie5T_JjEuJTEJRHpNfMb5xzrHAakb-Lfxu19nAVq7Rgd586m7UyfmB-pbe1XXNHnxjO7p-d11HdaJr14_dRAwvdD32vQ3J9ZZu3NDQ2r5Me6RuoOnV0rnvxn7rNK3dpw30Wsfp0Ixh_7pZ3j_hKTlqdRft7-95Qv4ub57nd2z1eHs_v1oxg1WZWCu5NEZUKDUXdttmUGWNAVkgiNKikCWaTDa5ya3I29JmEjItTNFsZV7kW8xOyJ9Dro_JqWhcsubV-GGwJimQWEghJuj8AO2C_xhtTOrNj2GYeiksRQmykign6vJAmeBjDLZVu-B6Hb4UcLXXoCYNaqEQ1F6Dguw_ERZ5Xg</recordid><startdate>20211201</startdate><enddate>20211201</enddate><creator>Banta, Robert M.</creator><creator>Pichugina, Yelena L.</creator><creator>Darby, Lisa S.</creator><creator>Brewer, W. Alan</creator><creator>Olson, Joseph B.</creator><creator>Kenyon, Jaymes S.</creator><creator>Baidar, S.</creator><creator>Benjamin, S.G.</creator><creator>Fernando, H.J.S.</creator><creator>Lantz, K.O.</creator><creator>Lundquist, J.K.</creator><creator>McCarty, B.J.</creator><creator>Marke, T.</creator><creator>Sandberg, S.P.</creator><creator>Sharp, J.</creator><creator>Shaw, W.J.</creator><creator>Turner, D.D.</creator><creator>Wilczak, J.M.</creator><creator>Worsnop, R.</creator><creator>Stoelinga, M.T.</creator><general>American Meteorological Society</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7QH</scope><scope>7TG</scope><scope>7TN</scope><scope>7UA</scope><scope>C1K</scope><scope>F1W</scope><scope>H96</scope><scope>KL.</scope><scope>L.G</scope><scope>U9A</scope><scope>OIOZB</scope><scope>OTOTI</scope></search><sort><creationdate>20211201</creationdate><title>Doppler-Lidar Evaluation of HRRR-Model Skill at Simulating Summertime Wind Regimes in the Columbia River Basin during WFIP2</title><author>Banta, Robert M. ; Pichugina, Yelena L. ; Darby, Lisa S. ; Brewer, W. 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(NREL), Golden, CO (United States)</creatorcontrib><collection>CrossRef</collection><collection>Aqualine</collection><collection>Meteorological & Geoastrophysical Abstracts</collection><collection>Oceanic Abstracts</collection><collection>Water Resources Abstracts</collection><collection>Environmental Sciences and Pollution Management</collection><collection>ASFA: Aquatic Sciences and Fisheries Abstracts</collection><collection>Aquatic Science & Fisheries Abstracts (ASFA) 2: Ocean Technology, Policy & Non-Living Resources</collection><collection>Meteorological & Geoastrophysical Abstracts - Academic</collection><collection>Aquatic Science & Fisheries Abstracts (ASFA) Professional</collection><collection>OSTI.GOV - Hybrid</collection><collection>OSTI.GOV</collection><jtitle>Weather and forecasting</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Banta, Robert M.</au><au>Pichugina, Yelena L.</au><au>Darby, Lisa S.</au><au>Brewer, W. Alan</au><au>Olson, Joseph B.</au><au>Kenyon, Jaymes S.</au><au>Baidar, S.</au><au>Benjamin, S.G.</au><au>Fernando, H.J.S.</au><au>Lantz, K.O.</au><au>Lundquist, J.K.</au><au>McCarty, B.J.</au><au>Marke, T.</au><au>Sandberg, S.P.</au><au>Sharp, J.</au><au>Shaw, W.J.</au><au>Turner, D.D.</au><au>Wilczak, J.M.</au><au>Worsnop, R.</au><au>Stoelinga, M.T.</au><aucorp>National Renewable Energy Lab. (NREL), Golden, CO (United States)</aucorp><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Doppler-Lidar Evaluation of HRRR-Model Skill at Simulating Summertime Wind Regimes in the Columbia River Basin during WFIP2</atitle><jtitle>Weather and forecasting</jtitle><date>2021-12-01</date><risdate>2021</risdate><volume>36</volume><issue>6</issue><spage>1961</spage><pages>1961-</pages><issn>0882-8156</issn><eissn>1520-0434</eissn><abstract>Complex-terrain locations often have repeatable near-surface wind patterns, such as synoptic gap flows and local thermally forced flows. An example is the Columbia River Valley in east-central Oregon-Washington, a significant wind-energy-generation region and the site of the Second Wind-Forecast Improvement Project (WFIP2). Data from three Doppler lidars deployed during WFIP2 define and characterize summertime wind regimes and their large-scale contexts, and provide insight into NWP model errors by examining differences in the ability of a model [NOAA’s High-Resolution Rapid-Refresh (HRRR-version1)] to forecast wind-speed profiles for different regimes. Seven regimes were identified based on daily time series of the lidar-measured rotor-layer winds, which then suggested two broad categories. First, in three regimes the primary dynamic forcing was the large-scale pressure gradient. Second, in two regimes the dominant forcing was the diurnal heating-cooling cycle (regional sea-breeze-type dynamics), including the
marine intrusion
previously described, which generates strong nocturnal winds over the region. The other two included a hybrid regime and a non-conforming regime. For the large-scale pressure-gradient regimes, HRRR had wind-speed biases of ~1 m s
−1
and RMSEs of 2-3 m s
−1
. Errors were much larger for the thermally forced regimes, owing to the premature demise of the strong nocturnal flow in HRRR. Thus, the more dominant the role of surface heating in generating the flow, the larger the errors. Major errors could result from surface heating of the atmosphere, boundary-layer responses to that heating, and associated terrain interactions. Measurement/modeling research programs should be aimed at determining which modeled processes produce the largest errors, so those processes can be improved and errors reduced.</abstract><cop>Boston</cop><pub>American Meteorological Society</pub><doi>10.1175/WAF-D-21-0012.1</doi><oa>free_for_read</oa></addata></record> |
| fulltext | fulltext |
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| ispartof | Weather and forecasting, 2021-12, Vol.36 (6), p.1961 |
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| language | eng |
| recordid | cdi_osti_scitechconnect_1825877 |
| source | American Meteorological Society; EZB-FREE-00999 freely available EZB journals; Alma/SFX Local Collection |
| subjects | Atmospheric boundary layer Atmospheric models Boundary layers Doppler lidar Doppler sonar Errors Forecast improvement Heating Lidar Mathematical models Modelling Nocturnal Pressure gradients Research programs River basins River valleys Rivers Sea breezes Surface wind Terrain weather weather model weather prediction Wind WIND ENERGY Wind power Wind profiles Wind speed Winds |
| title | Doppler-Lidar Evaluation of HRRR-Model Skill at Simulating Summertime Wind Regimes in the Columbia River Basin during WFIP2 |
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