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1. On Bridging A Modeling Scale Gap: Mesoscale to Microscale Coupling for Wind Energy

Author

Domingo Muñoz-Esparza, Rao Kotamarthi, Branko Kosovic, Michael Robinson, Brandon Lee Ennis, Matthew J. Churchfield, Raj K. Rai, Caroline Draxl, Gökhan Sever, Patrick Moriarty, Laura Mazzaro, Eunmo Koo, Sue Ellen Haupt, Joel Cline, Eliot Quon, William J. Shaw, Jeffrey D. Mirocha, and Larry K. Berg

Subjects
Atmospheric Science, Bridging (networking), Wind power, 010504 meteorology & atmospheric sciences, Scale (ratio), business.industry, 020209 energy, Flow (psychology), Mesoscale meteorology, 02 engineering and technology, 01 natural sciences, Coupling (computer programming), 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Aerospace engineering, business, Microscale chemistry, 0105 earth and related environmental sciences
Abstract

Accurately representing flow across the mesoscale to the microscale is a persistent roadblock for completing realistic microscale simulations. The science challenges that must be addressed to coupling at these scales include the following: 1) What is necessary to capture the variability of the mesoscale flow, and how do we avoid generating spurious rolls within the terra incognita between the scales? 2) Which methods effectively couple the mesoscale to the microscale and capture the correct nonstationary features at the microscale? 3) What are the best methods to initialize turbulence at the microscale? 4) What is the best way to handle the surface-layer parameterizations consistently at the mesoscale and the microscale? 5) How do we assess the impact of improvements in each of these aspects and quantify the uncertainty in the simulations? The U.S. Department of Energy Mesoscale-to-Microscale-Coupling project seeks to develop, verify, and validate physical models and modeling techniques that bridge the most important atmospheric scales determining wind plant performance and reliability, which impacts many meteorological applications. The approach begins with choosing case days that are interesting for wind energy for which there are observational data for validation. The team has focused on modeling nonstationary conditions for both flat and complex terrain. This paper describes the approaches taken to answer the science challenges, culminating in recommendations for best approaches for coupled modeling.

Published
2019

2. Improving Wind Energy Forecasting through Numerical Weather Prediction Model Development

Author

Irina Djalalova, Elena Akish, Kathy Lantz, Caroline Draxl, Branko Kosovic, Katherine McCaffrey, Melinda Marquis, David D. Turner, Aditya Choukulkar, Michael D. Toy, Stephanie Redfern, Laura Bianco, Wayne M. Angevine, Yelena L. Pichugina, Jim McCaa, Katherine A. Lundquist, Joel Cline, Robert M. Banta, William J. Shaw, Pedro A. Jiménez, Julie K. Lundquist, John M. Brown, Charles N. Long, Joseph B. Olson, James M. Wilczak, Jian-Wen Bao, Larry K. Berg, and Jaymes S. Kenyon

Subjects
Atmospheric Science, Wind power, 010504 meteorology & atmospheric sciences, Meteorology, business.industry, 020209 energy, Weather forecasting, Terrain, 02 engineering and technology, Numerical weather prediction, computer.software_genre, 01 natural sciences, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Model development, Second wind (sleep), business, computer, 0105 earth and related environmental sciences
Abstract

The primary goal of the Second Wind Forecast Improvement Project (WFIP2) is to advance the state-of-the-art of wind energy forecasting in complex terrain. To achieve this goal, a comprehensive 18-month field measurement campaign was conducted in the region of the Columbia River basin. The observations were used to diagnose and quantify systematic forecast errors in the operational High-Resolution Rapid Refresh (HRRR) model during weather events of particular concern to wind energy forecasting. Examples of such events are cold pools, gap flows, thermal troughs/marine pushes, mountain waves, and topographic wakes. WFIP2 model development has focused on the boundary layer and surface-layer schemes, cloud–radiation interaction, the representation of drag associated with subgrid-scale topography, and the representation of wind farms in the HRRR. Additionally, refinements to numerical methods have helped to improve some of the common forecast error modes, especially the high wind speed biases associated with early erosion of mountain–valley cold pools. This study describes the model development and testing undertaken during WFIP2 and demonstrates forecast improvements. Specifically, WFIP2 found that mean absolute errors in rotor-layer wind speed forecasts could be reduced by 5%–20% in winter by improving the turbulent mixing lengths, horizontal diffusion, and gravity wave drag. The model improvements made in WFIP2 are also shown to be applicable to regions outside of complex terrain. Ongoing and future challenges in model development will also be discussed.

Published
2019

3. The Second Wind Forecast Improvement Project (WFIP2): General Overview

Author

Melinda Marquis, Justin Sharp, Jim McCaa, William J. Shaw, Joel Cline, Chitra Sivaraman, James M. Wilczak, Eric P. Grimit, Caroline Draxl, Larry K. Berg, Julie K. Lundquist, Joseph B. Olson, and Irina Djalalova

Subjects
Atmospheric Science, Boundary layer, 010504 meteorology & atmospheric sciences, Meteorology, 020209 energy, 0202 electrical engineering, electronic engineering, information engineering, Representation (systemics), 02 engineering and technology, Second wind (sleep), 01 natural sciences, Energy (signal processing), 0105 earth and related environmental sciences
Abstract

In 2015 the U.S. Department of Energy (DOE) initiated a 4-yr study, the Second Wind Forecast Improvement Project (WFIP2), to improve the representation of boundary layer physics and related processes in mesoscale models for better treatment of scales applicable to wind and wind power forecasts. This goal challenges numerical weather prediction (NWP) models in complex terrain in large part because of inherent assumptions underlying their boundary layer parameterizations. The WFIP2 effort involved the wind industry, universities, the National Oceanographic and Atmospheric Administration (NOAA), and the DOE’s national laboratories in an integrated observational and modeling study. Observations spanned 18 months to assure a full annual cycle of continuously recorded observations from remote sensing and in situ measurement systems. The study area comprised the Columbia basin of eastern Washington and Oregon, containing more than 6 GW of installed wind capacity. Nests of observational systems captured important atmospheric scales from mesoscale to NWP subgrid scale. Model improvements targeted NOAA’s High-Resolution Rapid Refresh (HRRR) model to facilitate transfer of improvements to National Weather Service (NWS) operational forecast models, and these modifications have already yielded quantitative improvements for the short-term operational forecasts. This paper describes the general WFIP2 scope and objectives, the particular scientific challenges of improving wind forecasts in complex terrain, early successes of the project, and an integrated approach to archiving observations and model output. It provides an introduction for a set of more detailedBAMSpapers addressing WFIP2 observational science, modeling challenges and solutions, incorporation of forecasting uncertainty into decision support tools for the wind industry, and advances in coupling improved mesoscale models to microscale models that can represent interactions between wind plants and the atmosphere.

Published
2019

4. Measuring the impact of additional instrumentation on the skill of numerical weather prediction models at forecasting wind ramp events during the first Wind Forecast Improvement Project (WFIP)

Author

Elena Akish, James M. Wilczak, Laura Bianco, Irina Djalalova, Catherine Finley, Jeffrey Freedman, Joel Cline, and Joseph B. Olson

Subjects
Wind forecast, Wind power, Data assimilation, Meteorology, Renewable Energy, Sustainability and the Environment, business.industry, Environmental science, Numerical weather prediction models, Instrumentation (computer programming), business
Published
2019

5. Data assimilation impact of in situ and remote sensing meteorological observations on wind power forecasts during the first <scp>W</scp> ind <scp>F</scp> orecast <scp>I</scp> mprovement <scp>P</scp> roject (WFIP)

Author

Irina Djalalova, Catherine Finley, Joel Cline, Richard M. Eckman, William J. Shaw, Richard Coulter, Jeffrey Freedman, James M. Wilczak, Larry K. Berg, Laura Bianco, and Joseph B. Olson

Subjects
In situ, Wind forecast, Wind power, Data assimilation, Renewable Energy, Sustainability and the Environment, business.industry, Remote sensing (archaeology), Environmental science, business, Remote sensing
Published
2019

6. Learning from Hurricane Maria’s Impacts on Puerto Rico: A Progress Report

Author

Katherine J. Johnson, Judith Mitrani-Reiser, Erica D. Kuligowski, Thomas D. Kirsch, Joel Cline, Benjamin Davis, Marc L. Levitan, Jennifer Helgeson, Maria Dillard, Joseph A. Main, Scott Weaver, Luis D. Aponte-Bermúdez, DongHun Yeo, Jazalyn Dukes, and Kenneth Harrison

Subjects
Engineering, business.industry, business
Published
2021

8. Large-eddy simulation sensitivities to variations of configuration and forcing parameters in canonical boundary-layer flows for wind energy applications

Author

Raj K. Rai, Yan Feng, Shreyas Ananthan, Ramesh Balakrishnan, Branko Kosovic, Rodman R. Linn, Barbara G. Brown, Michael Robinson, Javier Sanz Rodrigo, Domingo Muñoz-Esparza, Larry K. Berg, Brandon Lee Ennis, Patrick Moriarty, Matthew J. Churchfield, Sue Ellen Haupt, Caroline Draxl, William J. Shaw, Joel Cline, Veerabhadra R. Kotamarthi, and Jeffrey D. Mirocha

Subjects
Physics, Wind power, 010504 meteorology & atmospheric sciences, Renewable Energy, Sustainability and the Environment, business.industry, Turbulence, Planetary boundary layer, lcsh:TJ807-830, lcsh:Renewable energy sources, Energy Engineering and Power Technology, Mechanics, Atmospheric sciences, 01 natural sciences, Wind speed, 010305 fluids & plasmas, Physics::Fluid Dynamics, Boundary layer, 0103 physical sciences, Turbulence kinetic energy, business, Geostrophic wind, 0105 earth and related environmental sciences, Large eddy simulation
Abstract

The sensitivities of idealized Large-Eddy Simulations (LES) to variations of model configuration and forcing parameters on quantities of interest to wind power applications are examined. Simulated wind speed, turbulent fluxes, spectra and cospectra are assessed in relation to variations of two physical factors, geostrophic wind speed and surface roughness length, and several model configuration choices, including mesh size and grid aspect ratio, turbulence model, and numerical discretization schemes, in three different code bases. Two case studies representing nearly steady neutral and convective atmospheric boundary layer (ABL) flow conditions over nearly flat and homogeneous terrain were used to force and assess idealized LES, using periodic lateral boundary conditions. Comparison with fast-response velocity measurements at five heights within the lowest 50 m indicates that most model configurations performed similarly overall, with differences between observed and predicted wind speed generally smaller than measurement variability. Simulations of convective conditions produced turbulence quantities and spectra that matched the observations well, while those of neutral simulations produced good predictions of stress, but smaller than observed magnitudes of turbulence kinetic energy, likely due to tower wakes influencing the measurements. While sensitivities to model configuration choices and variability in forcing can be considerable, idealized LES are shown to reliably reproduce quantities of interest to wind energy applications within the lower ABL during quasi-ideal, nearly steady neutral and convective conditions over nearly flat and homogeneous terrain.

Published
2018

9. Evaluating and Improving NWP Forecast Models for the Future: How the Needs of Offshore Wind Energy Can Point the Way

Author

Yelena L. Pichugina, Joel Cline, Joseph B. Olson, Laura Bianco, Jacob R. Carley, W. Alan Brewer, Stanley G. Benjamin, Eric James, James M. Wilczak, Robert M. Banta, Melinda Marquis, R. Michael Hardesty, and Irina Djalalova

Subjects
Atmospheric Science, 010504 meteorology & atmospheric sciences, Meteorology, 020209 energy, Mesoscale meteorology, 02 engineering and technology, 01 natural sciences, Offshore wind power, Lidar, Wind profile power law, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Spatial variability, Submarine pipeline, Air quality index, Rapid Refresh, 0105 earth and related environmental sciences
Abstract

To advance the understanding of meteorological processes in offshore coastal regions, the spatial variability of wind profiles must be characterized and uncertainties (errors) in NWP model wind forecasts quantified. These gaps are especially critical for the new offshore wind energy industry, where wind profile measurements in the marine atmospheric layer spanned by wind turbine rotor blades, generally 50–200 m above mean sea level (MSL), have been largely unavailable. Here, high-quality wind profile measurements were available every 15 min from the National Oceanic and Atmospheric Administration/Earth System Research Laboratory (NOAA/ESRL)’s high-resolution Doppler lidar (HRDL) during a monthlong research cruise in the Gulf of Maine for the 2004 New England Air Quality Study. These measurements were compared with retrospective NWP model wind forecasts over the area using two NOAA forecast-modeling systems [North American Mesoscale Forecast System (NAM) and Rapid Refresh (RAP)]. HRDL profile measurements quantified model errors, including their dependence on height above sea level, diurnal cycle, and forecast lead time. Typical model wind speed errors were ∼2.5 m s−1, and vector-wind errors were ∼4 m s−1. Short-term forecast errors were larger near the surface—30% larger below 100 m than above and largest for several hours after local midnight (biased low). Longer-term, 12-h forecasts had the largest errors after local sunset (biased high). At more than 3-h lead times, predictions from finer-resolution models exhibited larger errors. Horizontal variability of winds, measured as the ship traversed the Gulf of Maine, was significant and raised questions about whether modeled fields, which appeared smooth in comparison, were capturing this variability. If not, horizontal arrays of high-quality, vertical-profiling devices will be required for wind energy resource assessment offshore. Such measurement arrays are also needed to improve NWP models.

Published
2018

10. Assessment of NWP Forecast Models in Simulating Offshore Winds through the Lower Boundary Layer by Measurements from a Ship-Based Scanning Doppler Lidar

Author

Eric James, Irina Djalalova, W. Alan Brewer, Melinda Marquis, Joel Cline, James M. Wilczak, Robert M. Banta, Yelena L. Pichugina, Stanley G. Benjamin, Jacob R. Carley, Joseph B. Olson, and Laura Bianco

Subjects
Atmospheric Science, Wind power, 010504 meteorology & atmospheric sciences, Meteorology, business.industry, Planetary boundary layer, 010502 geochemistry & geophysics, Numerical weather prediction, 01 natural sciences, Wind speed, Boundary layer, symbols.namesake, Lidar, Wind shear, symbols, Environmental science, business, Doppler effect, 0105 earth and related environmental sciences
Abstract

Evaluation of model skill in predicting winds over the ocean was performed by comparing retrospective runs of numerical weather prediction (NWP) forecast models to shipborne Doppler lidar measurements in the Gulf of Maine, a potential region for U.S. coastal wind farm development. Deployed on board the NOAA R/V Ronald H. Brown during a 2004 field campaign, the high-resolution Doppler lidar (HRDL) provided accurate motion-compensated wind measurements from the water surface up through several hundred meters of the marine atmospheric boundary layer (MABL). The quality and resolution of the HRDL data allow detailed analysis of wind flow at heights within the rotor layer of modern wind turbines and data on other critical variables to be obtained, such as wind speed and direction shear, turbulence, low-level jet properties, ramp events, and many other wind-energy-relevant aspects of the flow. This study will focus on the quantitative validation of NWP models’ wind forecasts within the lower MABL by comparison with HRDL measurements. Validation of two modeling systems rerun in special configurations for these 2004 cases—the hourly updated Rapid Refresh (RAP) system and a special hourly updated version of the North American Mesoscale Forecast System [NAM Rapid Refresh (NAMRR)]—are presented. These models were run at both normal-resolution (RAP, 13 km; NAMRR, 12 km) and high-resolution versions: the NAMRR-CONUS-nest (4 km) and the High-Resolution Rapid Refresh (HRRR, 3 km). Each model was run twice: with (experimental runs) and without (control runs) assimilation of data from 11 wind profiling radars located along the U.S. East Coast. The impact of the additional assimilation of the 11 profilers was estimated by comparing HRDL data to modeled winds from both runs. The results obtained demonstrate the importance of high-resolution lidar measurements to validate NWP models and to better understand what atmospheric conditions may impact the accuracy of wind forecasts in the marine atmospheric boundary layer. Results of this research will also provide a first guess as to the uncertainties of wind resource assessment using NWP models in one of the U.S. offshore areas projected for wind plant development.

Published
2017

11. The Verification and Validation Strategy Within the Second Wind Forecast Improvement Project (WFIP 2)

Author

Joel Cline, Jim McCaa, Jaymes S. Kenyon, Timothy A. Bonin, Andrew Clifton, J. Olson, Eric P. Grimit, Aditya Choukulkar, C. N. Long, Larry K. Berg, Irina Djalalova, Julie K. Lundquist, Caroline Draxl, Virendra P. Ghate, J. F. Newman, William J. Shaw, K. Holub, Laura Bianco, Yelena L. Pichugina, Katherine McCaffrey, M. D. Toy, N. H. Smith, Justin Sharp, and Kathleen Lantz

Subjects
Environmental science, Second wind (sleep), Marine engineering, Verification and validation
Published
2019

12. The second wind forecast improvement project (wfip2) observational field campaign

Author

Nicola Bodini, Andrew Clifton, Justin Sharp, Yelena L. Pichugina, William J. Shaw, George Scott, Sonia Wharton, Charles N. Long, S. Otarola-Bustos, Laura Bianco, Harindra J. S. Fernando, Joseph B. Olson, Joel Cline, Robert M. Banta, James M. Wilczak, David R. Cook, Duli Chand, Larry K. Berg, Katherine McCaffrey, Caroline Draxl, Aditya Choukulkar, Jim McCaa, Jim Bickford, Kathleen Lantz, Julie K. Lundquist, Laura S. Leo, Raghavendra Krishnamurthy, Melinda Marquis, Paytsar Muradyan, Richard M. Eckman, Timothy A. Bonin, Katja Friedrich, Allen B. White, Mark T. Stoelinga, Irina Djalalova, R. Worsnop, Wilczak J.M., Stoelinga M., Berg L.K., Sharp J., Draxl C., McCaffrey K., Banta R.M., Bianco L., Djalalova I., Lundquist J.K., Muradyan P., Choukulkar A., Leo L., Bonin T., Pichugina Y., Eckman R., Long C.N., Lantz K., Worsnop R.P., Bickford J., Bodini N., Chand D., Clifton A., Cline J., Cook D.R., Fernando H.J.S., Friedrich K., Krishnamurthy R., Marquis M., McCaa J., Olson J.B., Otarola-Bustos S., Scott G., Shaw W.J., Wharton S., and White A.B.

Subjects
Atmospheric Science, 010504 meteorology & atmospheric sciences, Meteorology, RANGE, 020209 energy, AIR, 02 engineering and technology, TURBINE, DOPPLER LIDAR, 01 natural sciences, EVOLUTION, MOUNTAIN LEE WAVES, LAYER, WEATHER RESEARCH, GAP-FLOW, 0202 electrical engineering, electronic engineering, information engineering, WAKE, Environmental science, Observational study, Second wind (sleep), Administration (government), Field campaign, 0105 earth and related environmental sciences
Abstract

The Second Wind Forecast Improvement Project (WFIP2) is a U.S. Department of Energy (DOE)- and National Oceanic and Atmospheric Administration (NOAA)-funded program, with private-sector and university partners, which aims to improve the accuracy of numerical weather prediction (NWP) model forecasts of wind speed in complex terrain for wind energy applications. A core component of WFIP2 was an 18-month field campaign that took place in the U.S. Pacific Northwest between October 2015 and March 2017. A large suite of instrumentation was deployed in a series of telescoping arrays, ranging from 500 km across to a densely instrumented 2 km × 2 km area similar in size to a high-resolution NWP model grid cell. Observations from these instruments are being used to improve our understanding of the meteorological phenomena that affect wind energy production in complex terrain and to evaluate and improve model physical parameterization schemes. We present several brief case studies using these observations to describe phenomena that are routinely difficult to forecast, including wintertime cold pools, diurnally driven gap flows, and mountain waves/wakes. Observing system and data product improvements developed during WFIP2 are also described.

Published
2019

13. The POWER Experiment: Impact of Assimilation of a Network of Coastal Wind Profiling Radars on Simulating Offshore Winds in and above the Wind Turbine Layer

Author

James M. Wilczak, Yelena L. Pichugina, Joel Cline, Joseph B. Olson, Robert M. Banta, Laura Bianco, Melinda Marquis, Jacob R. Carley, and Irina Djalalova

Subjects
Atmospheric Science, 010504 meteorology & atmospheric sciences, Meteorology, 010505 oceanography, business.industry, Numerical weather prediction, 01 natural sciences, Turbine, Research vessel, Renewable energy, Offshore wind power, Lidar, Climatology, Environmental science, Submarine pipeline, business, Air quality index, 0105 earth and related environmental sciences
Abstract

During the summer of 2004 a network of 11 wind profiling radars (WPRs) was deployed in New England as part of the New England Air Quality Study (NEAQS). Observations from this dataset are used to determine their impact on numerical weather prediction (NWP) model skill at simulating coastal and offshore winds through data-denial experiments. This study is a part of the Position of Offshore Wind Energy Resources (POWER) experiment, a Department of Energy (DOE) sponsored project that uses National Oceanic and Atmospheric Administration (NOAA) models for two 1-week periods to measure the impact of the assimilation of observations from 11 inland WPRs. Model simulations with and without assimilation of the WPR data are compared at the locations of the inland WPRs, as well as against observations from an additional WPR and a high-resolution Doppler lidar (HRDL) located on board the Research Vessel Ronald H. Brown (RHB), which cruised the Gulf of Maine during the NEAQS experiment. Model evaluation in the lowest 2 km above the ground shows a positive impact of the WPR data assimilation from the initialization time through the next five to six forecast hours at the WPR locations for 12 of 15 days analyzed, when offshore winds prevailed. A smaller positive impact at the RHB ship track was also confirmed. For the remaining three days, during which time there was a cyclone event with strong onshore wind flow, the assimilation of additional observations had a negative impact on model skill. Explanations for the negative impact are offered.

Published
2016

14. A Wind Energy Ramp Tool and Metric for Measuring the Skill of Numerical Weather Prediction Models

Author

Irina Djalalova, Elena Konopleva-Akish, Stan Calvert, James M. Wilczak, Cathy Finley, Jeffrey Freedman, Joel Cline, and Laura Bianco

Subjects
Condensed Matter::Quantum Gases, Atmospheric Science, Wind power, 010504 meteorology & atmospheric sciences, Electrical load, business.industry, Computer science, 020209 energy, Forecast skill, 02 engineering and technology, Grid, 01 natural sciences, Power (physics), Amplitude, Control theory, Metric (mathematics), 0202 electrical engineering, electronic engineering, information engineering, Physics::Accelerator Physics, Duration (project management), business, 0105 earth and related environmental sciences
Abstract

A wind energy Ramp Tool and Metric (RT&M) has been developed out of recognition that during significant ramp events (large changes in wind power over short periods of time ) it is more difficult to balance the electric load with power production than during quiescent periods between ramp events. A ramp-specific metric is needed because standard metrics do not give special consideration to ramp events and hence may not provide an appropriate measure of model skill or skill improvement. This RT&M has three components. The first identifies ramp events in the power time series. The second matches in time forecast and observed ramps. The third determines a skill score of the forecast model. This is calculated from a utility operator’s perspective, incorporates phase and duration errors in time as well as power amplitude errors, and recognizes that up and down ramps have different impacts on grid operation. The RT&M integrates skill over a matrix of ramp events of varying amplitudes and durations.

Published
2016

15. The Wind Forecast Improvement Project (WFIP): A Public–Private Partnership Addressing Wind Energy Forecast Needs

Author

Cathy Finley, Stan Benjamin, Richard Coulter, Mark Ahlstrom, John Manobianco, Jeffrey Freedman, Irina Djalalova, James M. Wilczak, Jacob R. Carley, Joseph B. Olson, K. L. Clawson, Larry K. Berg, Edward Natenberg, Melinda Marquis, John Zack, Laura Bianco, Joel Cline, Jeffrey D. Mirocha, and Lindsay M. Sheridan

Subjects
Atmospheric Science, Public–private partnership, Research program, Wind forecast, Wind power, Meteorology, Nacelle, business.industry, Environmental science, Grid, business
Abstract

The Wind Forecast Improvement Project (WFIP) is a public–private research program, the goal of which is to improve the accuracy of short-term (0–6 h) wind power forecasts for the wind energy industry. WFIP was sponsored by the U.S. Department of Energy (DOE), with partners that included the National Oceanic and Atmospheric Administration (NOAA), private forecasting companies (WindLogics and AWS Truepower), DOE national laboratories, grid operators, and universities. WFIP employed two avenues for improving wind power forecasts: first, through the collection of special observations to be assimilated into forecast models and, second, by upgrading NWP forecast models and ensembles. The new observations were collected during concurrent year-long field campaigns in two high wind energy resource areas of the United States (the upper Great Plains and Texas) and included 12 wind profiling radars, 12 sodars, several lidars and surface flux stations, 184 instrumented tall towers, and over 400 nacelle anemometers. Results demonstrate that a substantial reduction (12%–5% for forecast hours 1–12) in power RMSE was achieved from the combination of improved numerical weather prediction models and assimilation of new observations, equivalent to the previous decade’s worth of improvements found for low-level winds in NOAA/National Weather Service (NWS) operational weather forecast models. Data-denial experiments run over select periods of time demonstrate that up to a 6% improvement came from the new observations. Ensemble forecasts developed by the private sector partners also produced significant improvements in power production and ramp prediction. Based on the success of WFIP, DOE is planning follow-on field programs.

Published
2015

16. Recent Trends in Variable Generation Forecasting and Its Value to the Power System

Author

Joel Cline, James M. Wilczak, Venkat Banunarayanan, Kirsten Orwig, Justin Sharp, Melinda Marquis, Bri-Mathias Hodge, Hendrik F. Hamann, Sue Ellen Haupt, Mark Ahlstrom, Jack Peterson, Dora Nakafuji, David Maggio, Obadiah Bartholomy, Catherine Finley, and Jeffrey Freedman

Subjects
Engineering, Wind power, Meteorology, Renewable Energy, Sustainability and the Environment, business.industry, Environmental economics, Solar energy, GeneralLiterature_MISCELLANEOUS, Solar power forecasting, Variable (computer science), Electric power system, Software deployment, ComputerApplications_MISCELLANEOUS, Electric power industry, business, Solar power
Abstract

The rapid deployment of wind and solar energy generation systems has resulted in a need to better understand, predict, and manage variable generation. The uncertainty around wind and solar power forecasts is still viewed by the power industry as being quite high, and many barriers to forecast adoption by power system operators still remain. In response, the U.S. Department of Energy has sponsored, in partnership with the National Oceanic and Atmospheric Administration, public, private, and academic organizations, two projects to advance wind and solar power forecasts. Additionally, several utilities and grid operators have recognized the value of adopting variable generation forecasting and have taken great strides to enhance their usage of forecasting. In parallel, power system markets and operations are evolving to integrate greater amounts of variable generation. This paper will discuss the recent trends in wind and solar power forecasting technologies in the U.S., the role of forecasting in an evolving power system framework, and the benefits to intended forecast users.

Published
2015

17. Task 36 Forecasting for Wind Power

Author

Gregor Giebel, Helmut Frank, Joel Cline, Will Shaw, Pierre Pinson, Bri-Mathias Hodge, Jakob Messner, Georges Kariniotakis, Caroline Draxl, Corinna Möhrlen, DTU Wind Energy, Deutscher Wetterdienst [Offenbach] (DWD), Department of Energy / Joint Genome Institute (DOE), Los Alamos National Laboratory (LANL), Pacific Northwest National Laboratory (PNNL), DTU Electrical Engineering [Lyngby], Technical University of Denmark [Lyngby] (DTU), NREL, US Department of Energy, Centre Procédés, Énergies Renouvelables, Systèmes Énergétiques (PERSEE), MINES ParisTech - École nationale supérieure des mines de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL), and WEPROG Aps

Subjects
[MATH.MATH-PR]Mathematics [math]/Probability [math.PR], [STAT.AP]Statistics [stat]/Applications [stat.AP], [STAT.ML]Statistics [stat]/Machine Learning [stat.ML], [MATH.MATH-ST]Mathematics [math]/Statistics [math.ST], [SPI.NRJ]Engineering Sciences [physics]/Electric power, [MATH.MATH-OC]Mathematics [math]/Optimization and Control [math.OC], ComputingMilieux_MISCELLANEOUS
Abstract

International audience

Published
2017

18. The new IEA Wind Task 36 on Wind Power Forecasting

Author

Gregor Giebel, Joel Cline, Helmut Frank, Will Shaw, Bri-Mathias Hodge, Pierre Pinson, George Kariniotakis, Caroline Draxi, Risø National Laboratory for Sustainable Energy (Risø DTU), Technical University of Denmark [Lyngby] (DTU), Pacific Northwest National Laboratory (PNNL), NREL, US Department of Energy, Centre Procédés, Énergies Renouvelables, Systèmes Énergétiques (PERSEE), MINES ParisTech - École nationale supérieure des mines de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL), Risø National Laboratory for Sustainable Energy ( Risø DTU ), Technical University of Denmark [Lyngby] ( DTU ), Pacific Northwest National Laboratory ( PNNL ), Centre Procédés, Énergies Renouvelables, Systèmes Énergétiques ( PERSEE ), and MINES ParisTech - École nationale supérieure des mines de Paris-PSL Research University ( PSL )

Subjects
[ SPI.ENERG ] Engineering Sciences [physics]/domain_spi.energ, [SPI.ENERG]Engineering Sciences [physics]/domain_spi.energ
Abstract

International audience; Wind power forecasts have been used operatively for over 20 years. Despite this fact, there are still several possibilities to improve the forecasts, both from the weather prediction side and from the usage of the forecasts. The new International Energy Agency (IEA) Task on Forecasting for Wind Energy tries to organise international collaboration, among national weather centres with an interest and/or large projects on wind forecast improvements (NOAA, DWD, …), operational forecaster and forecast users. The Task is divided in three work packages: Firstly, a collaboration on the improvement of the scientific basis for the wind predictions themselves. This includes numerical weather prediction model physics, but also widely distributed information on accessible datasets. Secondly, we will be aiming at an international pre-standard (an IEA Recommended Practice) on benchmarking and comparing wind power forecasts, including probabilistic forecasts. This WP will also organise benchmarks, in cooperation with the IEA Task WakeBench. Thirdly, we will be engaging end users aiming at dissemination of the best practice in the usage of wind power predictions.

Published
2015

19. Wind power forecasting: IEA Wind Task 36 & future research issues

Author

Helmut Frank, Bri-Mathias Hodge, Pierre Pinson, Corinna Möhrlen, Georges Kariniotakis, Joel Cline, Jens Madsen, William J. Shaw, Gregor Giebel, Risø National Laboratory for Sustainable Energy ( Risø DTU ), Technical University of Denmark [Lyngby] ( DTU ), Deutscher Wetterdienst [Offenbach] ( DWD ), Pacific Northwest National Laboratory ( PNNL ), NREL, US Department of Energy, Centre Procédés, Énergies Renouvelables, Systèmes Énergétiques ( PERSEE ), MINES ParisTech - École nationale supérieure des mines de Paris-PSL Research University ( PSL ), VATTENFALL, Research and Development, WEPROG Aps, Risø National Laboratory for Sustainable Energy (Risø DTU), Technical University of Denmark [Lyngby] (DTU), Deutscher Wetterdienst [Offenbach] (DWD), Pacific Northwest National Laboratory (PNNL), Centre Procédés, Énergies Renouvelables, Systèmes Énergétiques (PERSEE), MINES ParisTech - École nationale supérieure des mines de Paris, and Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)

Subjects
History, Engineering, Operations research, 020209 energy, Weather forecasting, Wind power forecasting, forecasting, 02 engineering and technology, computer.software_genre, 7. Clean energy, Education, Task (project management), [SPI.ENERG]Engineering Sciences [physics]/domain_spi.energ, 0202 electrical engineering, electronic engineering, information engineering, [ SPI.ENERG ] Engineering Sciences [physics]/domain_spi.energ, Wind power, End user, business.industry, 020208 electrical & electronic engineering, Benchmarking, Numerical weather prediction, Computer Science Applications, 13. Climate action, Consensus forecast, business, computer
Abstract

International audience; This paper presents the new International Energy Agency Wind Task 36 on Forecasting, and invites to collaborate within the group. Wind power forecasts have been used operatively for over 20 years. Despite this fact, there are still several possibilities to improve the forecasts, both from the weather prediction side and from the usage of the forecasts. The new International Energy Agency (IEA) Task on Forecasting for Wind Energy tries to organise international collaboration, among national meteorological centres with an interest and/or large projects on wind forecast improvements (NOAA, DWD, MetOffice, met.no, DMI,...), operational forecaster and forecast users. The Task is divided in three work packages: Firstly, a collaboration on the improvement of the scientific basis for the wind predictions themselves. This includes numerical weather prediction model physics, but also widely distributed information on accessible datasets. Secondly, we will be aiming at an international pre-standard (an IEA Recommended Practice) on benchmarking and comparing wind power forecasts, including probabilistic forecasts. This WP will also organise benchmarks, in cooperation with the IEA Task WakeBench. Thirdly, we will be engaging end users aiming at dissemination of the best practice in the usage of wind power predictions. As first results, an overview of current issues for research in short-term forecasting of wind power is presented.

Published
2016

20. The Objective Use of Observed and Forecast Thickness Values to Predict Precipitation Type in North Carolina

Author

Joel Cline and Kermit Keeter

Subjects
Atmospheric Science, Meteorology, Regression analysis, Stepwise regression, Snow, Logistic regression, Atmospheric sciences, Regression, law.invention, law, Quantitative precipitation forecast, Radiosonde, Environmental science, Precipitation
Abstract

The Local Objective Guidance for Predicting Precipitation Type (LOG/PT) consists of regression equations and nomograms. LOG/PT was designed to address problems inherent in forecasting wintry precipitation across North Carolina, where frozen and freezing precipitation are relatively infrequent, often occurring from mixed precipitation events, and where even small amounts can disrupt communities. Moreover, LOG/PT is an example of employing developmental strategies to maximize the yield from limited resources to produce an objective forecast tool for a critical local-forecast problem. Stepwise linear regression, with modifications to approximate the sigmoid curve associated with logit regression, was used to derive relationships between precipitation type and 1000–700-, 850–700-, and 1000–850-mb thickness values from radiosonde observations (raobs). The soundings were concurrent with, or within 12 h prior to, the onset of the precipitation at the prediction sites. The regression portion of LOG/PT di...

Published
1991

22. Submarine seepage of natural gas in norton sound, alaska

Author

Joel Cline and Mark L. Holmes

Subjects
geography, Multidisciplinary, geography.geographical_feature_category, business.industry, Continental shelf, Geochemistry, Structural basin, Plume, Petroleum seep, Oceanography, Fuel gas, Natural gas, Energy source, Structural geology, business, Geology
Abstract

Unusual concentrations of dissolved two- to four-carbon alkanes were observed in the waters in Norton Sound in a localized area approximately 40 kilometers south of Nome, Alaska, in 1976. The hydrocarbons were identified in the near-bottom waters downcurrent for more than 100 kilometers from a sea-floor point source. Preliminary dynamic modeling estimates of the initial gas phase composition predict methanelethane and ethanelpropane ratios of 24 and 1.7, respectively, assuming the hydrocarbons were introduced by bubbles. The low ethanelpropane ratio is indicative of gas from a liquid petroleum source rather than from nonassociated or biogenic natural gas. Preliminary data on the structural geology of Norton Basin lend support to the interpretation based on the hydrocarbon plume. Unconformably truncated strata dip basinward from the seep locus; acoustic anomalies and numerous steeply dipping faults in the immediate vicinity of the seep are corroborating evidence that shallow gas- or petroleum-charged sediments and strata coincide with avenues for migration of mobile hydrocarbons to the sea floor. These factors, taken in concert with the sedimentological regime, the recent revision (increase) of basin depth estimates, and the highly localized hydrocarbon source, strongly suggest a thermogenic rather than a recent biogenic origin for these gaseous compounds.

Published
1977

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