Your search keyword '"Burkely T. Gallo"' showing total 20 results

1. Exploring Applications of Storm-Scale Probabilistic Warn-on-Forecast Guidance in Weather Forecasting.

Author

Katie A. Wilson, Jessica J. Choate, Adam J. Clark, Burkely T. Gallo, Pamela L. Heinselman, Kent H. Knopfmeier, Brett Roberts, Patrick S. Skinner, and Nusrat Yussouf

Published

2019

2. Model Configuration versus Driving Model: Influences on Next-Day Regional Convection-Allowing Model Forecasts during a Real-Time Experiment

Author

Brett Roberts, Adam J. Clark, Israel L. Jirak, Burkely T. Gallo, Caroline Bain, David L. A. Flack, James Warner, Craig S. Schwartz, and Larissa J. Reames

Subjects

Atmospheric Science

Abstract

As part of NOAA’s Hazardous Weather Testbed Spring Forecasting Experiment (SFE) in 2020, an international collaboration yielded a set of real-time convection-allowing model (CAM) forecasts over the contiguous United States in which the model configurations and initial/boundary conditions were varied in a controlled manner. Three model configurations were employed, among which the Finite Volume Cubed-Sphere (FV3), Unified Model (UM), and Advanced Research version of the Weather Research and Forecasting (WRF-ARW) Model dynamical cores were represented. Two runs were produced for each configuration: one driven by NOAA’s Global Forecast System for initial and boundary conditions, and the other driven by the Met Office’s operational global UM. For 32 cases during SFE2020, these runs were initialized at 0000 UTC and integrated for 36 h. Objective verification of model fields relevant to convective forecasting illuminates differences in the influence of configuration versus driving model pertinent to the ongoing problem of optimizing spread and skill in CAM ensembles. The UM and WRF configurations tend to outperform FV3 for forecasts of precipitation, thermodynamics, and simulated radar reflectivity; using a driving model with the native CAM core also tends to produce better skill in aggregate. Reflectivity and thermodynamic forecasts were found to cluster more by configuration than by driving model at lead times greater than 18 h. The two UM configuration experiments had notably similar solutions that, despite competitive aggregate skill, had large errors in the diurnal convective cycle.

Published

2023

3. The Third Real-Time, Virtual Spring Forecasting Experiment to Advance Severe Weather Prediction Capabilities

Author

Adam J. Clark, Israel L. Jirak, Burkely T. Gallo, Brett Roberts, Kent H. Knopfmeier, Jake Vancil, David Jahn, Makenzie Krocak, Christopher D. Karstens, Eric D. Loken, Nathan A. Dahl, David Harrison, David Imy, Andrew R. Wade, Jeffrey M. Milne, Kimberly A. Hoogewind, Montgomery Flora, Joshua Martin, Brian C. Matilla, Joseph C. Picca, Corey K. Potvin, Patrick S. Skinner, and Patrick Burke

Subjects

Atmospheric Science

Published

2023

4. An Iterative Storm Segmentation and Classification Algorithm for Convection-Allowing Models and Gridded Radar Analyses

Author

Corey K. Potvin, Burkely T. Gallo, Anthony E. Reinhart, Brett Roberts, Patrick S. Skinner, Ryan A. Sobash, Katie A. Wilson, Kelsey C. Britt, Chris Broyles, Montgomery L. Flora, William J. S. Miller, and Clarice N. Satrio

Subjects

Atmospheric Science, Ocean Engineering

Abstract

Thunderstorm mode strongly impacts the likelihood and predictability of tornadoes and other hazards, and thus is of great interest to severe weather forecasters and researchers. It is often impossible for a forecaster to manually classify all the storms within convection-allowing model (CAM) output during a severe weather outbreak, or for a scientist to manually classify all storms in a large CAM or radar dataset in a timely manner. Automated storm classification techniques facilitate these tasks and provide objective inputs to operational tools, including machine learning models for predicting thunderstorm hazards. Accurate storm classification, however, requires accurate storm segmentation. Many storm segmentation techniques fail to distinguish between clustered storms, thereby missing intense cells, or to identify cells embedded within quasi-linear convective systems that can produce tornadoes and damaging winds. Therefore, we have developed an iterative technique that identifies these constituent storms in addition to traditionally identified storms. Identified storms are classified according to a seven-mode scheme designed for severe weather operations and research. The classification model is a hand-developed decision tree that operates on storm properties computed from composite reflectivity and midlevel rotation fields. These properties include geometrical attributes, whether the storm contains smaller storms or resides within a larger-scale complex, and whether strong rotation exists near the storm centroid. We evaluate the classification algorithm using expert labels of 400 storms simulated by the NSSL Warn-on-Forecast System or analyzed by the NSSL Multi-Radar/Multi-Sensor product suite. The classification algorithm emulates expert opinion reasonably well (e.g., 76% accuracy for supercells), and therefore could facilitate a wide range of operational and research applications. Significance Statement We have developed a new technique for automatically identifying intense thunderstorms in model and radar data and classifying storm mode, which informs forecasters about the risks of tornadoes and other high-impact weather. The technique identifies storms that are often missed by other methods, including cells embedded within storm clusters, and successfully classifies important storm modes that are generally not included in other schemes, such as rotating cells embedded within quasi-linear convective systems. We hope the technique will facilitate a variety of forecasting and research efforts.

Published

2022

5. Exploring the Usefulness of Downscaling Free Forecasts from the Warn-on-Forecast System

Author

William J. S. Miller, Corey K. Potvin, Montgomery L. Flora, Burkely T. Gallo, Louis J. Wicker, Thomas A. Jones, Patrick S. Skinner, Brian C. Matilla, and Kent H. Knopfmeier

Subjects

Atmospheric Science

Abstract

The National Severe Storms Laboratory (NSSL) Warn-on-Forecast System (WoFS) is an experimental real-time rapidly updating convection-allowing ensemble that provides probabilistic short-term thunderstorm forecasts. This study evaluates the impacts of reducing the forecast model horizontal grid spacing Δx from 3 to 1.5 km on the WoFS deterministic and probabilistic forecast skill, using 11 case days selected from the 2020 NOAA Hazardous Weather Testbed (HWT) Spring Forecasting Experiment (SFE). Verification methods include (i) subjective forecaster impressions; (ii) a deterministic object-based technique that identifies forecast reflectivity and rotation track storm objects as contiguous local maxima in the composite reflectivity and updraft helicity fields, respectively, and matches them to observed storm objects; and (iii) a recently developed algorithm that matches observed mesocyclones to mesocyclone probability swath objects constructed from the full ensemble of rotation track objects. Reducing Δx fails to systematically improve deterministic skill in forecasting reflectivity object occurrence, as measured by critical success index (CSIDET), a metric that incorporates both probability of detection (PODDET) and false alarm ratio (FARDET). However, compared to the Δx = 3 km configuration, the Δx = 1.5 km WoFS shows improved midlevel mesocyclone detection, as evidenced by its statistically significant (i) higher CSIDET for deterministic midlevel rotation track objects and (ii) higher normalized area under the performance diagram curve (NAUPDC) score for probability swath objects. Comparison between Δx = 3 km and Δx = 1.5 km reflectivity object properties reveals that the latter have 30% stronger mean updraft speeds, 17% stronger median 80-m winds, 67% larger median hail diameter, and 28% higher median near-storm-maximum 0–3-km storm-relative helicity.

Published

2022

6. The Second Real-Time, Virtual Spring Forecasting Experiment to Advance Severe Weather Prediction

Author

Adam J. Clark, Israel L. Jirak, Burkely T. Gallo, Kent H. Knopfmeier, Brett Roberts, Makenzie Krocak, Jake Vancil, Kimberly A. Hoogewind, Nathan A. Dahl, Eric D. Loken, David Jahn, David Harrison, David Imy, Patrick Burke, Louis J. Wicker, Patrick S. Skinner, Pamela L. Heinselman, Patrick Marsh, Katie A. Wilson, Andrew R. Dean, Gerald J. Creager, Thomas A. Jones, Jidong Gao, Yunheng Wang, Montgomery Flora, Corey K. Potvin, Christopher A. Kerr, Nusrat Yussouf, Joshua Martin, Jorge Guerra, Brian C. Matilla, and Thomas J. Galarneau

Subjects

Atmospheric Science

Published

2022

7. Exploring Convection-Allowing Model Evaluation Strategies for Severe Local Storms Using the Finite-Volume Cubed-Sphere (FV3) Model Core

Author

Jamie K. Wolff, Burkely T. Gallo, Tim Supinie, Yunheng Wang, Chunxi Zhang, Israel L. Jirak, Linjiong Zhou, Adam J. Clark, Ming Xue, Lindsay R. Blank, Lucas M. Harris, Curtis R. Alexander, and Brett Roberts

Subjects

Convection, Core (optical fiber), Atmospheric Science, Finite volume method, Severe weather, Weather forecasting, Storm, Geophysics, computer.software_genre, Cubed sphere, computer, Geology

Abstract

Verification methods for convection-allowing models (CAMs) should consider the finescale spatial and temporal detail provided by CAMs, and including both neighborhood and object-based methods can account for displaced features that may still provide useful information. This work explores both contingency table–based verification techniques and object-based verification techniques as they relate to forecasts of severe convection. Two key fields in severe weather forecasting are investigated: updraft helicity (UH) and simulated composite reflectivity. UH is used to generate severe weather probabilities called surrogate severe fields, which have two tunable parameters: the UH threshold and the smoothing level. Probabilities computed using the UH threshold and smoothing level that give the best area under the receiver operating curve result in very high probabilities, while optimizing the parameters based on the Brier score reliability component results in much lower probabilities. Subjective ratings from participants in the 2018 NOAA Hazardous Weather Testbed Spring Forecasting Experiment (SFE) provide a complementary evaluation source. This work compares the verification methodologies in the context of three CAMs using the Finite-Volume Cubed-Sphere Dynamical Core (FV3), which will be the foundation of the U.S. Unified Forecast System (UFS). Three agencies ran FV3-based CAMs during the five-week 2018 SFE. These FV3-based CAMs are verified alongside a current operational CAM, the High-Resolution Rapid Refresh version 3 (HRRRv3). The HRRR is planned to eventually use the FV3 dynamical core as part of the UFS; as such evaluations relative to current HRRR configurations are imperative to maintaining high forecast quality and informing future implementation decisions.

Published

2021

8. What Does a Convection-Allowing Ensemble of Opportunity Buy Us in Forecasting Thunderstorms?

Author

Brett Roberts, David C. Dowell, Burkely T. Gallo, Adam J. Clark, Yongming Wang, Israel L. Jirak, and Xuguang Wang

Subjects

Convection, Atmospheric Science, 010504 meteorology & atmospheric sciences, Meteorology, 0207 environmental engineering, Thunderstorm, Environmental science, 02 engineering and technology, 020701 environmental engineering, 01 natural sciences, 0105 earth and related environmental sciences

Abstract

The High Resolution Ensemble Forecast v2.1 (HREFv2.1), an operational convection-allowing model (CAM) ensemble, is an “ensemble of opportunity” wherein forecasts from several independently designed deterministic CAMs are aggregated and postprocessed together. Multiple dimensions of diversity in the HREFv2.1 ensemble membership contribute to ensemble spread, including model core, physics parameterization schemes, initial conditions (ICs), and time lagging. In this study, HREFv2.1 forecasts are compared against the High Resolution Rapid Refresh Ensemble (HRRRE) and the Multiscale data Assimilation and Predictability (MAP) ensemble, two experimental CAM ensembles that ran during the 5-week Spring Forecasting Experiment (SFE) in spring 2018. The HRRRE and MAP are formally designed ensembles with spread achieved primarily through perturbed ICs. Verification in this study focuses on composite radar reflectivity and updraft helicity to assess ensemble performance in forecasting convective storms. The HREFv2.1 shows the highest overall skill for these forecasts, matching subjective real-time impressions from SFE participants. Analysis of the skill and variance of ensemble member forecasts suggests that the HREFv2.1 exhibits greater spread and more effectively samples model uncertainty than the HRRRE or MAP. These results imply that to optimize skill in forecasting convective storms at 1–2-day lead times, future CAM ensembles should employ either diverse membership designs or sophisticated perturbation schemes capable of representing model uncertainty with comparable efficacy.

Published

2020

9. A Real-Time, Virtual Spring Forecasting Experiment to Advance Severe Weather Prediction

Author

Andrew R. Dean, William Miller, Pamela L. Heinselman, Kimberly A. Hoogewind, Katie A. Wilson, Montgomery L. Flora, Joshua Martin, Jake Vancil, Christopher A. Kerr, Adam J. Clark, Jidong Gao, Scott R. Dembek, Brian Matilla, David Harrison, Brett Roberts, Yunheng Wang, Nusrat Yussouf, Patrick S. Skinner, Nathan A. Dahl, Gerald J. Creager, Eric D. Loken, Burkely T. Gallo, Michael C. Coniglio, Kent H. Knopfmeier, David A. Imy, Louis J. Wicker, David E. Jahn, Jorge E. Guerra, Makenzie J. Krocak, Israel L. Jirak, and Thomas A. Jones

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, Severe weather, Meteorology, Spring (hydrology), Environmental science, Operational forecasting

Published

2021

10. A Real-Time, Simulated Forecasting Experiment for Advancing the Prediction of Hazardous Convective Weather

Author

Jessica J. Choate, Thomas A. Jones, Larissa J. Reames, Pamela L. Heinselman, Katie A. Wilson, Burkely T. Gallo, Robert A. Clark, Patrick S. Skinner, Kent H. Knopfmeier, Andrew R. Dean, Yunheng Wang, Brett Roberts, Louis J. Wicker, Jake Vancil, Adam J. Clark, Makenzie J. Krocak, Israel L. Jirak, Nathan A. Dahl, Scott R. Dembek, Gerald J. Creager, Steven J. Weiss, and Kimberly A. Hoogewind

Subjects

Convection, Atmospheric Science, Meteorology, Hazardous waste, Environmental science

Published

2020

11. Scorecards for Convection-Allowing Models

Author

Brett Roberts, Curtis R. Alexander, Tara Jensen, Henry H. Fisher, Israel L. Jirak, Christina Kalb, Burkely T. Gallo, John Halley Gotway, and Adam J. Clark

Subjects

Convection, Atmospheric Science, Mechanics, Geology

Published

2020

12. Initial Development and Testing of a Convection-Allowing Model Scorecard

Author

Tara Jensen, Henry H. Fisher, Israel L. Jirak, Christina Kalb, John Halley Gotway, Adam J. Clark, Brett Roberts, Burkely T. Gallo, and Curtis R. Alexander

Subjects

Convection, Atmospheric Science, Balanced scorecard, Computer science, Systems engineering, Numerical weather prediction, Strengths and weaknesses

Abstract

Evaluation of numerical weather prediction (NWP) is critical for both forecasters and researchers. Through such evaluation, forecasters can understand the strengths and weaknesses of NWP guidance, and researchers can work to improve NWP models. However, evaluating high-resolution convection-allowing models (CAMs) requires unique verification metrics tailored to high-resolution output, particularly when considering extreme events. Metrics used and fields evaluated often differ between verification studies, hindering the effort to broadly compare CAMs. The purpose of this article is to summarize the development and initial testing of a CAM-based scorecard, which is intended for broad use across research and operational communities and is similar to scorecards currently available within the enhanced Model Evaluation Tools package (METplus) for evaluating coarser models. Scorecards visualize many verification metrics and attributes simultaneously, providing a broad overview of model performance. A preliminary CAM scorecard was developed and tested during the 2018 Spring Forecasting Experiment using METplus, focused on metrics and attributes relevant to severe convective forecasting. The scorecard compared attributes specific to convection-allowing scales such as reflectivity and surrogate severe fields, using metrics like the critical success index (CSI) and fractions skill score (FSS). While this preliminary scorecard focuses on attributes relevant to severe convective storms, the scorecard framework allows for the inclusion of further metrics relevant to other applications. Development of a CAM scorecard allows for evidence-based decision-making regarding future operational CAM systems as the National Weather Service transitions to a Unified Forecast system as part of the Next-Generation Global Prediction System initiative.

Published

2019

13. Systematic Comparison of Convection-Allowing Models during the 2017 NOAA HWT Spring Forecasting Experiment

Author

Yongming Wang, Keith Brewster, Xuguang Wang, Corey K. Potvin, Eric A. Aligo, David C. Dowell, Ming Xue, Jacob R. Carley, Timothy A. Supinie, Anthony E. Reinhart, Lucas M. Harris, Israel L. Jirak, John S. Kain, Burkely T. Gallo, Glen S. Romine, Fanyou Kong, Louis J. Wicker, Adam J. Clark, Patrick S. Skinner, and Kevin W. Thomas

Subjects

Convection, Atmospheric Science, geography, geography.geographical_feature_category, Meteorology, Testbed, Convective storm detection, Spring (hydrology), Environmental science

Abstract

The 2016–18 NOAA Hazardous Weather Testbed (HWT) Spring Forecasting Experiments (SFE) featured the Community Leveraged Unified Ensemble (CLUE), a coordinated convection-allowing model (CAM) ensemble framework designed to provide empirical guidance for development of operational CAM systems. The 2017 CLUE included 81 members that all used 3-km horizontal grid spacing over the CONUS, enabling direct comparison of forecasts generated using different dynamical cores, physics schemes, and initialization procedures. This study uses forecasts from several of the 2017 CLUE members and one operational model to evaluate and compare CAM representation and next-day prediction of thunderstorms. The analysis utilizes existing techniques and novel, object-based techniques that distill important information about modeled and observed storms from many cases. The National Severe Storms Laboratory Multi-Radar Multi-Sensor product suite is used to verify model forecasts and climatologies of observed variables. Unobserved model fields are also examined to further illuminate important intermodel differences in storms and near-storm environments. No single model performed better than the others in all respects. However, there were many systematic intermodel and intercore differences in specific forecast metrics and model fields. Some of these differences can be confidently attributed to particular differences in model design. Model intercomparison studies similar to the one presented here are important to better understand the impacts of model and ensemble configurations on storm forecasts and to help optimize future operational CAM systems.

Published

2019

14. Analysis of End User Access of Warn-on-Forecast Guidance Products during an Experimental Forecasting Task

Author

Jessica J. Choate, Katie A. Wilson, Patrick S. Skinner, Burkely T. Gallo, Adam J. Clark, and Pamela L. Heinselman

Subjects

Atmospheric Science, Global and Planetary Change, End user, Human–computer interaction, Computer science, Social Sciences (miscellaneous), Task (project management)

Abstract

Convection-allowing model ensemble guidance, such as that provided by the Warn-on-Forecast System (WoFS), is designed to provide predictions of individual thunderstorm hazards within the next 0–6 h. The WoFS web viewer provides a large suite of storm and environmental attribute products, but the applicability of these products to the National Weather Service forecast process has not been objectively documented. Therefore, this study describes an experimental forecasting task designed to investigate what WoFS products forecasters accessed and how they accessed them for a total of 26 cases (comprised of 13 weather events, each worked by two forecasters). Analysis of web access log data revealed that in all 26 cases, product accesses were dominated in the reflectivity, rotation, hail, and surface wind categories. However, the number of different product types viewed and the number of transitions between products varied in each case. Therefore, the Levenshtein (Edit Distance) method was used to compute similarity scores across all 26 cases, which helped identify what it meant for relatively similar vs. dissimilar navigation of WoFS products. The Spearman’s Rank correlation coefficient (R) results found that forecasters working the same weather event had higher similarity scores for events that produced more tornado reports and for events in which forecasters had higher performance scores. The findings from this study will influence subsequent efforts for further improving WoFS products and developing an efficient and effective user interface for operational applications.

Published

2021

15. Incorporating UH Occurrence Time to Ensemble-Derived Tornado Probabilities

Author

Adam J. Clark, Scott R. Dembek, Burkely T. Gallo, Israel L. Jirak, Richard L. Thompson, and Bryan T. Smith

Subjects

Atmospheric Science, Meteorology, Environmental science, Tornado, Helicity, Occurrence time

Abstract

Probabilistic ensemble-derived tornado forecasts generated from convection-allowing models often use hourly maximum updraft helicity (UH) alone or in combination with environmental parameters as a proxy for right-moving (RM) supercells. However, when UH occurrence is a condition for tornado probability generation, false alarm areas can occur from UH swaths associated with nocturnal mesoscale convective systems, which climatologically produce fewer tornadoes than RM supercells. This study incorporates UH timing information with the forecast near-storm significant tornado parameter (STP) to calibrate the forecast tornado probability. To generate the probabilistic forecasts, three sets of observed climatological tornado frequencies given an RM supercell and STP value are incorporated with the model output, two of which use UH timing information. One method uses the observed climatological tornado frequency for a given 3-h window to generate the probabilities. Another normalizes the observed climatological tornado frequency by the number of hail, wind, and tornado reports observed in that 3-h window compared to the maximum number of reports in any 3-h window. The final method is independent of when UH occurs and uses the observed climatological tornado frequency encompassing all hours. The normalized probabilities reduce the false alarm area compared to the other methods but have a smaller area under the ROC curve and require a much higher percentile of the STP distribution to be used in probability generation to become reliable. Case studies demonstrate that the normalized probabilities highlight the most likely area for evening RM supercellular tornadoes, decreasing the nocturnal false alarm by assuming a linear convective mode.

Published

2019

16. The Community Leveraged Unified Ensemble (CLUE) in the 2016 NOAA/Hazardous Weather Testbed Spring Forecasting Experiment

Author

Gregory Thompson, Xiquan Dong, Gerry J. Creager, Israel L. Jirak, Rebecca D. Adams-Selin, Fanyou Kong, Matthew Pyle, Adam J. Clark, Ming Xue, Kevin W. Thomas, Curtis R. Alexander, Kent H. Knopfmeier, Christopher J. Melick, Matthew S. Gilmore, Ryan A. Sobash, Joshua Markel, Brad S. Ferrier, John S. Kain, Kathryn R. Fossell, Jacob R. Carley, Steven J. Weiss, Keith Brewster, Louis J. Wicker, Glen S. Romine, David A. Imy, Youngsun Jung, Burkely T. Gallo, Aaron Kennedy, and Scott R. Dembek

Subjects

Atmospheric Science, Government, Leverage (finance), 010504 meteorology & atmospheric sciences, Computer science, 0208 environmental biotechnology, Testbed, 02 engineering and technology, 01 natural sciences, Data science, 020801 environmental engineering, Environmental modeling, Hazardous waste, 0105 earth and related environmental sciences

Abstract

One primary goal of annual Spring Forecasting Experiments (SFEs), which are coorganized by NOAA’s National Severe Storms Laboratory and Storm Prediction Center and conducted in the National Oceanic and Atmospheric Administration’s (NOAA) Hazardous Weather Testbed, is documenting performance characteristics of experimental, convection-allowing modeling systems (CAMs). Since 2007, the number of CAMs (including CAM ensembles) examined in the SFEs has increased dramatically, peaking at six different CAM ensembles in 2015. Meanwhile, major advances have been made in creating, importing, processing, verifying, and developing tools for analyzing and visualizing these large and complex datasets. However, progress toward identifying optimal CAM ensemble configurations has been inhibited because the different CAM systems have been independently designed, making it difficult to attribute differences in performance characteristics. Thus, for the 2016 SFE, a much more coordinated effort among many collaborators was made by agreeing on a set of model specifications (e.g., model version, grid spacing, domain size, and physics) so that the simulations contributed by each collaborator could be combined to form one large, carefully designed ensemble known as the Community Leveraged Unified Ensemble (CLUE). The 2016 CLUE was composed of 65 members contributed by five research institutions and represents an unprecedented effort to enable an evidence-driven decision process to help guide NOAA’s operational modeling efforts. Eight unique experiments were designed within the CLUE framework to examine issues directly relevant to the design of NOAA’s future operational CAM-based ensembles. This article will highlight the CLUE design and present results from one of the experiments examining the impact of single versus multicore CAM ensemble configurations.

Published

2018

17. Breaking New Ground in Severe Weather Prediction: The 2015 NOAA/Hazardous Weather Testbed Spring Forecasting Experiment

Author

Rebecca D. Adams-Selin, Keith Brewster, James Correia, Eswar R. Iyer, Adam J. Clark, Derek R. Stratman, Burkely T. Gallo, Youngsun Jung, Ming Xue, Andrew R. Dean, Christopher J. Melick, Michael C. Coniglio, William Line, Steve Willington, Gregory W. Carbin, Feifei Shen, Kevin W. Thomas, Fanyou Kong, Kent H. Knopfmeier, Christopher D. Karstens, Steven J. Weiss, Israel L. Jirak, and John S. Kain

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Meteorology, 0208 environmental biotechnology, 02 engineering and technology, 01 natural sciences, 020801 environmental engineering, Environmental Modeling Center, Model output statistics, Hurricane Weather Research and Forecasting model, Weather Research and Forecasting Model, Environmental science, Probabilistic forecasting, Tropical cyclone forecast model, Rapid Refresh, North American Mesoscale Model, 0105 earth and related environmental sciences

Abstract

Led by NOAA’s Storm Prediction Center and National Severe Storms Laboratory, annual spring forecasting experiments (SFEs) in the Hazardous Weather Testbed test and evaluate cutting-edge technologies and concepts for improving severe weather prediction through intensive real-time forecasting and evaluation activities. Experimental forecast guidance is provided through collaborations with several U.S. government and academic institutions, as well as the Met Office. The purpose of this article is to summarize activities, insights, and preliminary findings from recent SFEs, emphasizing SFE 2015. Several innovative aspects of recent experiments are discussed, including the 1) use of convection-allowing model (CAM) ensembles with advanced ensemble data assimilation, 2) generation of severe weather outlooks valid at time periods shorter than those issued operationally (e.g., 1–4 h), 3) use of CAMs to issue outlooks beyond the day 1 period, 4) increased interaction through software allowing participants to create individual severe weather outlooks, and 5) tests of newly developed storm-attribute-based diagnostics for predicting tornadoes and hail size. Additionally, plans for future experiments will be discussed, including the creation of a Community Leveraged Unified Ensemble (CLUE) system, which will test various strategies for CAM ensemble design using carefully designed sets of ensemble members contributed by different agencies to drive evidence-based decision-making for near-future operational systems.

Published

2017

18. The High Resolution Ensemble Forecast (HREF) system: Applications and Performance for Forecasting Convective Storms

Author

Adam J. Clark, Brett Roberts, Burkely T. Gallo, and Israel L. Jirak

Subjects

Meteorology, Natural hazard, Convective storm detection, Environmental science, High resolution

Abstract

In November 2017, the High Resolution Ensemble Forecast version 2 (HREFv2) system was implemented by the U.S. National Oceanic and Atmospheric Administration (NOAA). The HREFv2 is NCEP’s first oper...

Published

2019

19. Forecasting Tornadoes Using Convection-Permitting Ensembles

Author

Scott R. Dembek, Burkely T. Gallo, and Adam J. Clark

Subjects

Convection, Atmospheric Science, 010504 meteorology & atmospheric sciences, Severe weather, Meteorology, 0208 environmental biotechnology, Probabilistic logic, Storm, 02 engineering and technology, 01 natural sciences, 020801 environmental engineering, Climatology, Weather Research and Forecasting Model, Environmental science, Tornado, Lifted condensation level, 0105 earth and related environmental sciences

Abstract

Hourly maximum fields of simulated storm diagnostics from experimental versions of convection-permitting models (CPMs) provide valuable information regarding severe weather potential. While past studies have focused on predicting any type of severe weather, this study uses a CPM-based Weather Research and Forecasting (WRF) Model ensemble initialized daily at the National Severe Storms Laboratory (NSSL) to derive tornado probabilities using a combination of simulated storm diagnostics and environmental parameters. Daily probabilistic tornado forecasts are developed from the NSSL-WRF ensemble using updraft helicity (UH) as a tornado proxy. The UH fields are combined with simulated environmental fields such as lifted condensation level (LCL) height, most unstable and surface-based CAPE (MUCAPE and SBCAPE, respectively), and multifield severe weather parameters such as the significant tornado parameter (STP). Varying thresholds of 2–5-km updraft helicity were tested with differing values of σ in the Gaussian smoother that was used to derive forecast probabilities, as well as different environmental information, with the aim of maximizing both forecast skill and reliability. The addition of environmental information improved the reliability and the critical success index (CSI) while slightly degrading the area under the receiver operating characteristic (ROC) curve across all UH thresholds and σ values. The probabilities accurately reflected the location of tornado reports, and three case studies demonstrate value to forecasters. Based on initial tests, four sets of tornado probabilities were chosen for evaluation by participants in the 2015 National Oceanic and Atmospheric Administration’s Hazardous Weather Testbed Spring Forecasting Experiment from 4 May to 5 June 2015. Participants found the probabilities useful and noted an overforecasting tendency.

Published

2016

20. CORRIGENDUM

Author

Burkely T. Gallo, Adam J. Clark, and Scott R. Dembek

Subjects

Atmospheric Science

Published

2016