Your search keyword '"Branko Kosovic"' showing total 29 results

1. Impact of Momentum Perturbation on Convective Boundary Layer Turbulence

Author

Mukesh Kumar, Alex Jonko, William Lassman, Jeffrey D. Mirocha, Branko Kosović, and Tirtha Banerjee

Subjects

convective boundary layer, large eddy simulation, nesting, turbulence generation, turbulence kinetic energy budget, Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract Mesoscale‐to‐microscale coupling is an important tool for conducting turbulence‐resolving multiscale simulations of realistic atmospheric flows, which are crucial for applications ranging from wind energy to wildfire spread studies. Different techniques are used to facilitate the development of realistic turbulence in the large‐eddy simulation (LES) domain while minimizing computational cost. Here, we explore the impact of a simple and computationally efficient Stochastic Cell Perturbation method using momentum perturbation (SCPM‐M) to accelerate turbulence generation in boundary‐coupled LES simulations using the Weather Research and Forecasting model. We simulate a convective boundary layer (CBL) to characterize the production and dissipation of turbulent kinetic energy (TKE) and the variation of TKE budget terms. Furthermore, we evaluate the impact of applying momentum perturbations of three magnitudes below, up to, and above the CBL on the TKE budget terms. Momentum perturbations greatly reduce the fetch associated with turbulence generation. When applied to half the vertical extent of the boundary layer, momentum perturbations produce an adequate amount of turbulence. However, when applied above the CBL, additional structures are generated at the top of the CBL, near the inversion layer. The magnitudes of the TKE budgets produced by SCPM‐M when applied at varying heights and with different perturbation amplitudes are always higher near the surface and inversion layer than those produced by No‐SCPM, as are their contributions to the TKE. This study provides a better understanding of how SCPM‐M reduces computational costs and how different budget terms contribute to TKE in a boundary‐coupled LES simulation.

Published

2024

2. Evaluating the performance of WRF in simulating winds and surface meteorology during a Southern California wildfire event

Author

Mukesh Kumar, Branko Kosović, Hara P. Nayak, William C. Porter, James T. Randerson, and Tirtha Banerjee

Subjects

fire-weather, grid resolution, nesting, PBL scheme, wildfires, WRF (weather research and forecasting), Science

Abstract

The intensity and frequency of wildfires in California (CA) have increased in recent years, causing significant damage to human health and property. In October 2007, a number of small fire events, collectively referred to as the Witch Creek Fire or Witch Fire started in Southern CA and intensified under strong Santa Ana winds. As a test of current mesoscale modeling capabilities, we use the Weather Research and Forecasting (WRF) model to simulate the 2007 wildfire event in terms of meteorological conditions. The main objectives of the present study are to investigate the impact of horizontal grid resolution and planetary boundary layer (PBL) scheme on the model simulation of meteorological conditions associated with a Mega fire. We evaluate the predictive capability of the WRF model to simulate key meteorological and fire-weather forecast parameters such as wind, moisture, and temperature. Results of this study suggest that more accurate predictions of temperature and wind speed relevant for better prediction of wildfire spread can be achieved by downscaling regional numerical weather prediction products to 1 km resolution. Furthermore, accurate prediction of near-surface conditions depends on the choice of the planetary boundary layer parameterization. The MYNN parameterization yields more accurate prediction as compared to the YSU parameterization. WRF simulations at 1 km resolution result in better predictions of temperature and wind speed than relative humidity during the 2007 Witch Fire. In summary, the MYNN PBL parameterization scheme with finer grid resolution simulations improves the prediction of near-surface meteorological conditions during a wildfire event.

Published

2024

3. Toward a Better Understanding of Wildfire Behavior in the Wildland‐Urban Interface: A Case Study of the 2021 Marshall Fire

Author

Timothy W. Juliano, Neil Lareau, Maria E. Frediani, Kasra Shamsaei, Masih Eghdami, Karen Kosiba, Joshua Wurman, Amy DeCastro, Branko Kosović, and Hamed Ebrahimian

Subjects

Geophysics. Cosmic physics, QC801-809

Abstract

Abstract On 30 December 2021, the Marshall Fire devastated the Boulder, Colorado region. The fire initiated in fine fuels in open space just southeast of Boulder and spread rapidly due to the strong, downslope winds that penetrated into the Boulder Foothills. Despite the increasing occurrence of wildland‐urban interface (WUI) disasters, many questions remain about how fires progress through vegetation and the built environment. To help answer these questions for the Marshall Fire, we use a coupled fire‐atmosphere model and Doppler on Wheels (DOW) observations to study the fire's progression as well as examine the physical drivers of its spread. Evaluation of the model using the DOW suggests that the model is able to capture general characteristics of the flow field; however, it does not produce as robust of a hydraulic jump as the one observed. Our results highlight limitations of the model that should be addressed for successful WUI simulations.

Published

2023

4. High‐Resolution Large‐Eddy Simulations of Flow in the Complex Terrain of the Canadian Rockies

Author

Mina Rohanizadegan, Richard M. Petrone, John W. Pomeroy, Branko Kosovic, Domingo Muñoz‐Esparza, and Warren D. Helgason

Subjects

Astronomy, QB1-991, Geology, QE1-996.5

Abstract

Abstract Improving the calculation of land‐atmosphere fluxes of heat and water vapor in mountain terrain requires better resolution of thermally driven diurnal winds (i.e., valley, slope winds) due to differential heating by terrain and radiative fluxes. In this study, the Weather Research and Forecasting model is used to simulate flow in large‐eddy simulation (LES) mode over the complex terrain of the Fortress Mountain and Marmot Creek research basins, Kananaskis Valley, Canadian Rockies, Alberta in mid‐summer. The model was used to examine the temporal and spatial evolution of local winds and near‐surface boundary layer processes with variability in topography and elevation. Numerically resolving complex terrain wind flow effects require smaller grid cell size. However, the use of terrain‐following coordinates in most numerical weather prediction models results in large numerical errors when flow over steep terrain is simulated. These errors propagate through the domain and can result in numerical instability. To avoid this issue when simulating flow over steep terrain a local smoothing approach was used, where smoothing is applied only where slope exceeds some predetermined threshold. LES results from local smoothing were compared with a mesoscale model and LES with global smoothing. Simulations are evaluated using sounding data and meteorological stations. The differences in flow patterns and reversals in two mountain basins suggest that valley geometry and volume is relevant to the break up of inversion layers, removal of cold‐air pools, and strength of thermally driven winds.

Published

2023

5. Evaluating the detectability of methane point sources from satellite observing systems using microscale modeling

Author

Piyush Bhardwaj, Rajesh Kumar, Douglas A. Mitchell, Cynthia A. Randles, Nicole Downey, Doug Blewitt, and Branko Kosovic

Subjects

Medicine, Science

Abstract

Abstract This study evaluates the efficacy of current satellite observing systems to detect methane point sources from typical oil and gas production (O&G) facilities using a novel very high-resolution methane concentration dataset generated using a microscale model. Transport and dispersion of typical methane emissions from seven well pads were simulated and the column enhancements for pseudo satellite pixel sizes of 3, 1, and 0.05 km were examined every second of the 2-h simulations (7200 realizations). The detectability of plumes increased with a pixel resolution, but two orders of magnitude change in emission rates at the surface results only in about 0.4%, 1.6%, and 47.8% enhancement in the pseudo-satellite retrieved methane column at 3, 1, and 0.05 km, respectively. Average methane emission rates estimated by employing the integrated mass enhancement (IME) method to column enhancements at 0.05 km showed an underestimation of the mean emissions by 0.2–6.4%. We show that IME derived satellite-based inversions of methane emissions work well for large persistent emission sources (e.g., super emitters), however, the method is ill-suited to resolve short-term emission fluctuations (

Published

2022

6. Characterizing the Role of Moisture and Smoke on the 2021 Santa Coloma de Queralt Pyroconvective Event Using WRF‐Fire

Author

Masih Eghdami, Timothy W. Juliano, Pedro A. Jiménez, Branko Kosovic, Marc Castellnou, Rajesh Kumar, and Jordi Vila‐Guerau de Arellano

Subjects

pyroconvective clouds, WRF‐fire, wildfire smoke, wildfire modeling, Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract Smoke from wildfires or burning biomass directly affects air quality and weather through modulating cloud microphysics and radiation. A simple wildfire emission coupling of black carbon (BC) and organic carbon (OC) with microphysics was implemented using the Weather Research and Forecasting model's fire module. A set of large‐eddy simulations inspired by unique surface and upper atmospheric observations from the 2021 Santa Coloma de Queralt Fire (Spain) were conducted to investigate the influence of background conditions and interactions between atmospheric and fire processes such as fire smoke, ambient moisture, and latent heat release on the formation and evolution of pyroconvective clouds. While the microphysical impact of BC and OC emissions on the dynamics of fire behavior is minimal on short time scales (

Published

2023

7. The Role of Fuel Characteristics and Heat Release Formulations in Coupled Fire-Atmosphere Simulation

Author

Kasra Shamsaei, Timothy W. Juliano, Matthew Roberts, Hamed Ebrahimian, Neil P. Lareau, Eric Rowell, and Branko Kosovic

Subjects

WRF-fire, canopy, crown fire, coupled fire-atmosphere simulation, mass loss, burning rate, Physics, QC1-999

Abstract

In this study, we focus on the effects of fuel bed representation and fire heat and smoke distribution in a coupled fire-atmosphere simulation platform for two landscape-scale fires: the 2018 Camp Fire and the 2021 Caldor Fire. The fuel bed representation in the coupled fire-atmosphere simulation platform WRF-Fire currently includes only surface fuels. Thus, we enhance the model by adding canopy fuel characteristics and heat release, for which a method to calculate the heat generated from canopy fuel consumption is developed and implemented in WRF-Fire. Furthermore, the current WRF-Fire heat and smoke distribution in the atmosphere is replaced with a heat-conserving Truncated Gaussian (TG) function and its effects are evaluated. The simulated fire perimeters of case studies are validated against semi-continuous, high-resolution fire perimeters derived from NEXRAD radar observations. Furthermore, simulated plumes of the two fire cases are compared to NEXRAD radar reflectivity observations, followed by buoyancy analysis using simulated temperature and vertical velocity fields. The results show that while the improved fuel bed and the TG heat release scheme have small effects on the simulated fire perimeters of the wind-driven Camp Fire, they affect the propagation direction of the plume-driven Caldor Fire, leading to better-matching fire perimeters with the observations. However, the improved fuel bed representation, together with the TG heat smoke release scheme, leads to a more realistic plume structure in comparison to the observations in both fires. The buoyancy analysis also depicts more realistic fire-induced temperature anomalies and atmospheric circulation when the fuel bed is improved.

Published

2023

8. A Multimodal Data Fusion and Deep Learning Framework for Large-Scale Wildfire Surface Fuel Mapping

Author

Mohamad Alipour, Inga La Puma, Joshua Picotte, Kasra Shamsaei, Eric Rowell, Adam Watts, Branko Kosovic, Hamed Ebrahimian, and Ertugrul Taciroglu

Subjects

wildland fire, fuel mapping, remote sensing, artificial intelligence, machine learning, deep learning, Physics, QC1-999

Abstract

Accurate estimation of fuels is essential for wildland fire simulations as well as decision-making related to land management. Numerous research efforts have leveraged remote sensing and machine learning for classifying land cover and mapping forest vegetation species. In most cases that focused on surface fuel mapping, the spatial scale of interest was smaller than a few hundred square kilometers; thus, many small-scale site-specific models had to be created to cover the landscape at the national scale. The present work aims to develop a large-scale surface fuel identification model using a custom deep learning framework that can ingest multimodal data. Specifically, we use deep learning to extract information from multispectral signatures, high-resolution imagery, and biophysical climate and terrain data in a way that facilitates their end-to-end training on labeled data. A multi-layer neural network is used with spectral and biophysical data, and a convolutional neural network backbone is used to extract the visual features from high-resolution imagery. A Monte Carlo dropout mechanism was also devised to create a stochastic ensemble of models that can capture classification uncertainties while boosting the prediction performance. To train the system as a proof-of-concept, fuel pseudo-labels were created by a random geospatial sampling of existing fuel maps across California. Application results on independent test sets showed promising fuel identification performance with an overall accuracy ranging from 55% to 75%, depending on the level of granularity of the included fuel types. As expected, including the rare—and possibly less consequential—fuel types reduced the accuracy. On the other hand, the addition of high-resolution imagery improved classification performance at all levels.

Published

2023

9. A Comprehensive Wind Power Forecasting System Integrating Artificial Intelligence and Numerical Weather Prediction

Author

Branko Kosovic, Sue Ellen Haupt, Daniel Adriaansen, Stefano Alessandrini, Gerry Wiener, Luca Delle Monache, Yubao Liu, Seth Linden, Tara Jensen, William Cheng, Marcia Politovich, and Paul Prestopnik

Subjects

grid integration, machine learning, renewable energy, turbine icing, wind power forecasting, wind energy, Technology

Abstract

The National Center for Atmospheric Research (NCAR) recently updated the comprehensive wind power forecasting system in collaboration with Xcel Energy addressing users’ needs and requirements by enhancing and expanding integration between numerical weather prediction and machine-learning methods. While the original system was designed with the primary focus on day-ahead power prediction in support of power trading, the enhanced system provides short-term forecasting for unit commitment and economic dispatch, uncertainty quantification in wind speed prediction with probabilistic forecasting, and prediction of extreme events such as icing. Furthermore, the empirical power conversion machine-learning algorithms now use a quantile approach to data quality control that has improved the accuracy of the methods. Forecast uncertainty is quantified using an analog ensemble approach. Two methods of providing short-range ramp forecasts are blended: the variational doppler radar analysis system and an observation-based expert system. Extreme events, specifically changes in wind power due to high winds and icing, are now forecasted by combining numerical weather prediction and a fuzzy logic artificial intelligence system. These systems and their recent advances are described and assessed.

Published

2020

10. Lessons learned in coupling atmospheric models across scales for onshore and offshore wind energy

Author

Sue Ellen Haupt, Branko Kosovic, Larry K. Berg, Colleen M. Kaul, Matthew Churchfield, Jeffrey Mirocha, Dries Allaerts, Thomas Brummet, Shannon Davis, Amy DeCastro, Susan Dettling, Caroline Draxl, David John Gagne, Patrick Hawbecker, Pankaj Jha, Timothy Juliano, William Lassman, Eliot Quon, Raj Rai, Michael Robinson, William Shaw, and Regis Thedin

Abstract

The Mesoscale to Microscale Coupling team, part of the U.S. Department of Energy Atmosphere to electrons (A2e) initiative, has studied various important challenges related to coupling mesoscale models to microscale models for the use case of wind energy development and operation. Several coupling methods and techniques for generating turbulence at the microscale that is subgrid to the mesoscale have been evaluated for a variety of cases. Case studies included flat terrain, complex terrain, and offshore environments. Methods were developed to bridge the terra incognita, that scale from about 100 m through the depth of the boundary layer. The team used wind-relevant metrics and archived code, case information, and assessment tools and are making those widely available. Lessons learned and discerned best practices are described in the context of the cases studied for the purpose of enabling further deployment of wind energy.

Published

2022

11. Enhancing wildfire spread modelling by building a gridded fuel moisture content product with machine learning

Author

Tyler C McCandless, Branko Kosovic, and William Petzke

Published

2020

12. The Bolzano Tracer Experiment (BTEX)

Author

Elena Tomasi, Luca Delle Monache, Pedro A. Jiménez, Lorenzo Giovannini, Enrico Ferrero, Marco Falocchi, Stefano Alessandrini, Werner Tirler, Gianluca Antonacci, Dino Zardi, and Branko Kosovic

Subjects

Tracer experiment, Atmospheric Science, Air pollution, Complex terrain, Dispersion, Lidars/Lidar observations, Mesoscale processes, Tracers, Environmental chemistry, Environmental science, BTEX

Abstract

The paper describes the observational and modeling efforts performed under the Bolzano Tracer Experiment (BTEX). BTEX focused on the basin surrounding the city of Bolzano, at the junction of three tributary valleys on the southern side of the Alps, to characterize the ground-level impact of pollutants emitted by a waste incinerator close to the city, and atmospheric factors controlling dispersion processes in the whole basin, under different winter weather situations. As part of the experiment, two controlled releases of a passive gas tracer (sulfur hexafluoride, SF6) were performed through the stack of the incinerator on 14 February 2017 at two different times, starting respectively at 0700 and 1245 LST, representative of distinct phases of the daily cycle. Samples of ambient air were collected at target sites, and later analyzed using a mass spectrometer, allowing a detectability limit down to 30 ppt. Meanwhile, meteorological conditions were continuously monitored by means of a high-resolution, nonconventional network of ground-based instruments, including 15 weather stations, one temperature profiler, one sodar, and one Doppler wind lidar. Data from the above measurements represent one of the rare examples of integrated datasets available to the community for the characterization of dispersion processes in a typical mountainous environment. In particular, they offered a reference benchmark for testing and calibrating a series of combined numerical modeling suites for weather prediction and pollutant dispersion simulation in such a complex terrain, as shown in the paper.

Published

2021

13. Combining Artificial Intelligence with Physics-Based Methods for Probabilistic Renewable Energy Forecasting

Author

William Petzke, Tyler McCandless, Jared A. Lee, Stefano Alessandrini, Seth Linden, Majed Al-Rasheedi, Thomas Brummet, Nhi Nguyen, Sue Ellen Haupt, Susan Dettling, Gerry Wiener, Tahani Hussain, and Branko Kosovic

Subjects

Control and Optimization, 010504 meteorology & atmospheric sciences, Computer science, 020209 energy, solar energy, Energy Engineering and Power Technology, 02 engineering and technology, lcsh:Technology, 01 natural sciences, wind energy, renewable energy forecasting, artificial intelligence, machine learning, Component (UML), 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Engineering (miscellaneous), 0105 earth and related environmental sciences, Relative value, Wind power, lcsh:T, Renewable Energy, Sustainability and the Environment, business.industry, Photovoltaic system, Probabilistic logic, Solar energy, Grid, Renewable energy, Artificial intelligence, business, Energy (miscellaneous)

Abstract

A modern renewable energy forecasting system blends physical models with artificial intelligence to aid in system operation and grid integration. This paper describes such a system being developed for the Shagaya Renewable Energy Park, which is being developed by the State of Kuwait. The park contains wind turbines, photovoltaic panels, and concentrated solar renewable energy technologies with storage capabilities. The fully operational Kuwait Renewable Energy Prediction System (KREPS) employs artificial intelligence (AI) in multiple portions of the forecasting structure and processes, both for short-range forecasting (i.e., the next six hours) as well as for forecasts several days out. These AI methods work synergistically with the dynamical/physical models employed. This paper briefly describes the methodology used for each of the AI methods, how they are blended, and provides a preliminary assessment of their relative value to the prediction system. Each operational AI component adds value to the system. KREPS is an example of a fully integrated state-of-the-science forecasting system for renewable energy.

Published

2020

14. 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

15. A methodology for the design and testing of atmospheric boundary layer models for wind energy applications

Author

Branko Kosovic, Javier Sanz Rodrigo, and Matthew J. Churchfield

Subjects

Physics, Wind power, 010504 meteorology & atmospheric sciences, Meteorology, Renewable Energy, Sustainability and the Environment, Planetary boundary layer, business.industry, lcsh:TJ807-830, Mesoscale meteorology, lcsh:Renewable energy sources, Energy Engineering and Power Technology, Wind direction, Atmospheric sciences, 01 natural sciences, Wind speed, 010305 fluids & plasmas, Wind profile power law, 13. Climate action, Weather Research and Forecasting Model, 0103 physical sciences, Reynolds-averaged Navier–Stokes equations, business, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences

Abstract

The GEWEX Atmospheric Boundary Layer Studies (GABLS) 1, 2 and 3 are used to develop a methodology for the design and testing of Reynolds-averaged Navier–Stokes (RANS) atmospheric boundary layer (ABL) models for wind energy applications. The first two GABLS cases are based on idealized boundary conditions and are suitable for verification purposes by comparing with results from higher-fidelity models based on large-eddy simulation. Results from three single-column RANS models, of 1st, 1.5th and 2nd turbulence closure order, show high consistency in predicting the mean flow. The third GABLS case is suitable for the study of these ABL models under realistic forcing such that validation versus observations from the Cabauw meteorological tower are possible. The case consists on a diurnal cycle that leads to a nocturnal low-level jet and addresses fundamental questions related to the definition of the large-scale forcing, the interaction of the ABL with the surface and the evaluation of model results with observations. The simulations are evaluated in terms of surface-layer fluxes and wind energy quantities of interest: rotor equivalent wind speed, hub-height wind direction, wind speed shear and wind direction veer. The characterization of mesoscale forcing is based on spatially and temporally averaged momentum budget terms from Weather Research and Forecasting (WRF) simulations. These mesoscale tendencies are used to drive single-column models, which were verified previously in the first two GABLS cases, to first demonstrate that they can produce similar wind profile characteristics to the WRF simulations even though the physics are more simplified. The added value of incorporating different forcing mechanisms into microscale models is quantified by systematically removing forcing terms in the momentum and heat equations. This mesoscale-to-microscale modeling approach is affected, to a large extent, by the input uncertainties of the mesoscale tendencies. Deviations from the profile observations are reduced by introducing observational nudging based on measurements that are typically available from wind energy campaigns. This allows the discussion of the added value of using remote sensing instruments versus tower measurements in the assessment of wind profiles for tall wind turbines reaching heights of 200 m.

Published

2017

16. A High Resolution Coupled Fire–Atmosphere Forecasting System to Minimize the Impacts of Wildland Fires: Applications to the Chimney Tops II Wildland Event

Author

Domingo Muñoz-Esparza, Pedro A. Jiménez, and Branko Kosovic

Subjects

040101 forestry, Smoke, Atmospheric Science, 010504 meteorology & atmospheric sciences, Meteorology, Event (computing), Terrain, 04 agricultural and veterinary sciences, Environmental Science (miscellaneous), TOPS, Numerical weather prediction, 01 natural sciences, atmospheric_science, Atmosphere, operational forecast sytem, fire modeling, numerical weather prediction, high spatial reoslution, WRF-Fire, Incident management (ITSM), 0401 agriculture, forestry, and fisheries, Environmental science, Chimney, 0105 earth and related environmental sciences

Abstract

Wildland fires are responsible for large socio-economic impacts. Fires affect the environment, damage structures, threaten lives, cause health issues, and involve large suppression costs. These impacts can be mitigated via accurate fire spread forecast to inform the incident management team. We show that a fire forecast system based on a numerical weather prediction (NWP) model coupled with a wildland fire behavior model can provide this forecast. This was illustrated with the Chimney Tops II wildland fire responsible for large socio-economic impacts. The system was run at high horizontal resolution (111 m) over the region affected by the fire to provide a fine representation of the terrain and fuel heterogeneities and explicitly resolve atmospheric turbulence. Our findings suggest that one can use the high spatial resolution winds, fire spread and smoke forecast to minimize the adverse impacts of wildland fires.

Published

2018

17. Meteorology For Coastal/Offshore Wind Energy In The United States: Recommendations And Research Needs For The Next 10 Years

Author

Anna C. Fitch, Bruce H. Bailey, Richard J. A. M. Stevens, Sang Lee, Branko Kosovic, Julie K. Lundquist, Patrick Moriarty, Brian A. Colle, Michael J. Dvorak, Matthew J. Churchfield, Cristina L. Archer, Luca Delle Monache, Hugo P. Simão, John Zack, Philippe Beaucage, Dana E. Veron, Physics of Fluids, and Faculty of Science and Technology

Subjects

Atmospheric Science, Offshore wind power, Meteorology, IR-88403, METIS-299814, Environmental science, Research needs

Published

2014

18. Resolved turbulence characteristics in large-eddy simulations nested within mesoscale simulations using the weather research and forecasting model

Author

Jeff Mirocha, Branko Kosovic, Gokhan Kirkil, and Kirkil, Gökhan

Subjects

Convection, Atmospheric Science, Meteorology, Turbulence, Flow (psychology), Mesoscale meteorology, Terrain, Atmospheric sciences, Wind speed, Physics::Fluid Dynamics, Weather Research and Forecasting Model, Turbulence kinetic energy, Geology, Physics::Atmospheric and Oceanic Physics

Abstract

One-way concurrent nesting within the Weather Research and Forecasting Model (WRF) is examined for conducting large-eddy simulations (LES) nested within mesoscale simulations. Wind speed, spectra, and resolved turbulent stresses and turbulence kinetic energy from the nested LES are compared with data from nonnested simulations using periodic lateral boundary conditions. Six different subfilter-scale (SFS) stress models are evaluated using two different nesting strategies under geostrophically forced flow over both flat and hilly terrain. Neutral and weakly convective conditions are examined. For neutral flow over flat terrain, turbulence appears on the nested LES domains only when using the two dynamic SFS stress models. The addition of small hills and valleys (wavelengths of 2.4 km and maximum slopes of ± 10°) yields small improvements, with all six models producing some turbulence on nested domains. Weak convection (surface heat fluxes of 10 W m−2) further accelerates the development of turbulence on all nested domains. However, considerable differences in key parameters are observed between the nested LES domains and their nonnested counterparts. Nesting of a finer LES within a coarser LES provides superior results to using only one nested LES domain. Adding temperature and velocity perturbations near the inlet planes of nested domains shows promise as an easy-to-implement method to accelerate turbulence generation and improve its accuracy on nested domains.

Published

2014

19. Machine Learning and VIIRS Satellite Retrievals for Skillful Fuel Moisture Content Monitoring in Wildfire Management

Author

John S. Schreck, William Petzke, Pedro A. Jiménez, Thomas Brummet, Jason C. Knievel, Eric James, Branko Kosović, and David John Gagne

Subjects

fuel moisture content, 10 h dead vegetation, machine learning models, wildland fires, VIIRS retrievals, Science

Abstract

Monitoring the fuel moisture content (FMC) of 10 h dead vegetation is crucial for managing and mitigating the impact of wildland fires. The combination of in situ FMC observations, numerical weather prediction (NWP) models, and satellite retrievals has facilitated the development of machine learning (ML) models to estimate 10 h dead FMC retrievals over the contiguous US (CONUS). In this study, ML models were trained using variables from the National Water Model, the High-Resolution Rapid Refresh (HRRR) NWP model, and static surface properties, along with surface reflectances and land surface temperature (LST) retrievals from the Visible Infrared Imaging Radiometer Suite (VIIRS) instrument on the Suomi-NPP satellite system. Extensive hyper-parameter optimization resulted in skillful FMC models compared to a daily climatography RMSE (+44%) and an hourly climatography RMSE (+24%). Notably, VIIRS retrievals played a significant role as predictors for estimating 10 h dead FMC, demonstrating their importance as a group due to their high band correlation. Conversely, individual predictors within the HRRR group exhibited relatively high importance according to explainability techniques. Removing both HRRR and VIIRS retrievals as model inputs led to a significant decline in performance, particularly with worse RMSE values when excluding VIIRS retrievals. The importance of the VIIRS predictor group reinforces the dynamic relationship between 10 h dead fuel, the atmosphere, and soil moisture. These findings underscore the significance of selecting appropriate data sources when utilizing ML models for FMC prediction. VIIRS retrievals, in combination with selected HRRR variables, emerge as critical components in achieving skillful FMC estimates.

Published

2023

20. An intercomparison of large-eddy simulations of the stable boundary layer

Author

Peter P. Sullivan, Julie K. Lundquist, Jean-Christophe Golaz, Albert A. M. Holtslag, Anne McCabe, Igor Esau, Maria A. Jiménez, David C. Lewellen, Branko Kosovic, Siegfried Raasch, Marat Khairoutdinov, Yign Noh, Arnold F. Moene, Thomas S. Lund, Joan Cuxart, Robert J. Beare, and M. K. Macvean

Subjects

Meteorologie en Luchtkwaliteit, Atmospheric Science, Earth science, Meteorology, Meteorology and Air Quality, Planetary boundary layer, Atmospheric boundary layer, Stability (probability), subgrid model, Atmospheric instability, Life Science, surface, Matematikk og Naturvitenskap: 400 [VDP], Physics::Atmospheric and Oceanic Physics, turbulence, resolution, transition, mesoscale, Numerical weather prediction, sensitivity, shallow cumulus convection, fluxes, cases-99, Boundary layer, Environmental science, Climate model, Parametrization, Large eddy simulation

Abstract

Results are presented from the first intercomparison of large-eddy simulation (LES) models for the stable boundary layer (SBL), as part of the Global Energy and Water Cycle Experiment Atmospheric Boundary Layer Study initiative. A moderately stable case is used, based on Arctic observations. All models produce successful simulations, in as much as they generate resolved turbulence and reflect many of the results from local scaling theory and observations. Simulations performed at 1-m and 2-m resolution show only small changes in the mean profiles compared to coarser resolutions. Also, sensitivity to subgrid models for individual models highlights their importance in SBL simulation at moderate resolution (6.25 m). Stability functions are derived from the LES using typical mixing lengths used in numerical weather prediction (NWP) and climate models. The functions have smaller values than those used in NWP. There is also support for the use of K-profile similarity in parametrizations. Thus, the results provide improved understanding and motivate future developments of the parametrization of the SBL. Keywords Large-eddy simulation

Published

2004

21. Efficient Graphics Processing Unit Modeling of Street‐Scale Weather Effects in Support of Aerial Operations in the Urban Environment

Author

Domingo Muñoz‐Esparza, Hyeyum Hailey Shin, Jeremy A. Sauer, Matthias Steiner, Patrick Hawbecker, Jennifer Boehnert, James O. Pinto, Branko Kosović, and Robert D. Sharman

Subjects

urban weather, large‐eddy simulation, GPU modeling, Geology, QE1-996.5, Geophysics. Cosmic physics, QC801-809

Abstract

Abstract Over the last few years, the concept of incorporating aerial vehicles into the urban environment for diverse purposes has attracted ample interest and investment. These purposes cover a broad spectrum of applications, from larger vehicles designed for passenger transport, to package delivery and inspection/surveillance missions performed by small unmanned drones. While these Advanced Air Mobility (AAM) operations have the potential to alleviate bottlenecks arising from saturated surface transportation networks, there are a number of challenges that need to be addressed to make these operations safe and viable. One challenge is predicting weather effects within the urban environment with the required level of spatiotemporal fidelity, which current operational weather models fail to provide due to the use of coarse grid spacings (a few kilometers) constrained by the predictive performance limitations of traditional computer architectures. Herein, we demonstrate how FastEddy®, a microscale model that exploits the accelerated nature of graphics processing units for high‐performance computing, can be used to understand and predict urban weather impacts from seasonal, day‐to‐day, diurnal, and sub‐hourly scales. To that end, we efficiently perform more than 50 telescoped simulations of microscale urban effects at street‐scale (5 m grid spacing) driven by realistic weather over a 20 km2 region centered at the downtown area of Dallas, Texas. Our analyses demonstrate that urban‐weather interactions at the street‐scale are complex and tightly connected, which is of utmost relevance to AAM operations. These demonstrations reveal the capability of such models to provide real‐time weather hazard avoidance products tailored to capture microscale urban effects.

Published

2021

22. Weather Research and Forecasting—Fire Simulated Burned Area and Propagation Direction Sensitivity to Initiation Point Location and Time

Author

Amy DeCastro, Amanda Siems-Anderson, Ebone Smith, Jason C. Knievel, Branko Kosović, Barbara G. Brown, and Jennifer K. Balch

Subjects

wildland fire detection, wildland fire behavior model, ignition point, sensitivity study, Physics, QC1-999

Abstract

Wildland fire behavior models are often initiated using the detection information listed in incident reports. This information carries an unknown amount of uncertainty, though it is often the most readily available ignition data. To determine the extent to which the use of detection information affects wildland fire forecasts, this research examines the range of burned area values and propagation directions resulting from different initiation point locations and times. We examined the forecasts for ten Colorado 2018 wildland fire case studies, each initiated from a set of 17 different point locations, and three different starting times (a total of 520 case study simulations). The results show that the range of forecast burned area and propagation direction values is strongly affected by the location of the initiation location, and to a lesser degree by the time of initiation.

Published

2022

23. A Computationally Efficient Method for Updating Fuel Inputs for Wildfire Behavior Models Using Sentinel Imagery and Random Forest Classification

Author

Amy L. DeCastro, Timothy W. Juliano, Branko Kosović, Hamed Ebrahimian, and Jennifer K. Balch

Subjects

wildland fire behavior model, fuel model, random forest, Sentinel, WRF-Fire, Science

Abstract

Disturbance events can happen at a temporal scale much faster than wildland fire fuel data updates. When used as input for wildland fire behavior models, outdated fuel datasets can contribute to misleading forecasts, which have implications for operational firefighting, mitigation, and wildland fire research. Remote sensing and machine learning methods can provide a solution for on-demand fuel estimation. Here, we show a proof of concept using C-band synthetic aperture radar and multispectral imagery, land cover classes, and tree mortality surveys to train a random forest classifier to estimate wildland fire fuel data in the East Troublesome Fire (Colorado) domain. The algorithm classified over 80% of the test dataset correctly, and the resulting wildland fire fuel data was used to simulate the East Troublesome Fire using the coupled atmosphere—wildland fire behavior model, WRF-Fire. The simulation using the modified fuel inputs, where 43% of original fuels are replaced with fuels representing dead trees, improved the burn area forecast by 38%. This study demonstrates the need for up-to-date fuel maps available in real time to provide accurate prediction of wildland fire spread, and outlines the methodology based on high-resolution satellite observations and machine learning that can accomplish this task.

Published

2022

24. Inclusion of Building‐Resolving Capabilities Into the FastEddy® GPU‐LES Model Using an Immersed Body Force Method

Author

Domingo Muñoz‐Esparza, Jeremy A. Sauer, Hyeyum Hailey Shin, Robert Sharman, Branko Kosović, Scott Meech, Clara García‐Sánchez, Matthias Steiner, Jason Knievel, James Pinto, and Scott Swerdlin

Subjects

Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract As a first step toward achieving full physics urban weather simulation capabilities within the resident‐GPU large‐eddy simulation (LES) FastEddy® model, we have implemented and verified/validated a method for explicit representation of building effects. Herein, we extend the immersed body force method (IBFM) from Chan and Leach (2007, https://doi.org/10.1175/2006JAMC1321.1) to (i) be scale independent and (ii) control building surface temperatures. Through a specific drag‐like term in the momentum equations, the IBFM is able to enforce essentially zero velocities within the buildings, in turn resulting in a no‐slip boundary condition at the building walls. In addition, we propose similar forcing terms in the energy and mass conservation equations that allow an accurate prescription of the building temperature. The extended IBFM is computationally efficient and has the potential to be coupled to building energy models. The IBFM exhibits excellent agreement with laboratory experiments of an array of staggered cubes at a grid spacing of Δ=1 mm, demonstrating the applicability of the method beyond the atmospheric scale. In addition, the IBFM is validated at atmospheric scale through simulations of downtown Oklahoma City ( Δ=2 m) using data collected during the Joint Urban 2003 (JU03) field campaign. Our LES IBFM results for mean wind speed, turbulence kinetic energy, and SF6 transport and dispersion compare well to observations and produce turbulence spectra that are in good agreement with sonic anemometer data. Statistical performance metrics for the JU03 simulations are within the range of other LES models in the literature.

Published

2020

25. Smoke from 2020 United States wildfires responsible for substantial solar energy forecast errors

Author

Timothy W Juliano, Pedro A Jiménez, Branko Kosović, Trude Eidhammer, Gregory Thompson, Larry K Berg, Jerome Fast, Amber Motley, and Andrea Polidori

Subjects

numerical weather prediction, solar energy, wildfire smoke emissions, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350, Science, Physics, QC1-999

Abstract

The 2020 wildfire season (May through December) in the United States was exceptionally active, with the National Interagency Fire Center reporting over 10 million acres ( $\gt$ 40 000 km ^2 ) burned. During the September 2020 wildfire events, large concentrations of smoke particulates were emitted into the atmosphere. As a result, smoke was responsible for ∼10%–30% reduction in solar power production during peak hours as recorded by the California Independent System Operator (CAISO) sites. In this study, we focus on a 9 d period in September when wildfire smoke had a profound impact on solar energy production. During the smoke episodes, hour-ahead forecasts utilized by CAISO did not include the effects of smoke and therefore overestimated the expected power production by ∼10%–50%. Here we use multiple observational networks and a numerical weather prediction (NWP) model to show that the wildfire events of 2020 had a significantly detrimental influence on solar energy production due to high aerosol loading. We find that including the contribution of biomass burning particles greatly improves the day-ahead solar energy bias forecast of both global horizontal irradiance and direct normal irradiance by nearly ∼50%. Our results suggest that a more comprehensive treatment of aerosols, including biomass burning aerosols, in NWP models may be an important consideration for energy grid balancing, in addition to solar resource assessment, as solar power reliance increases.

Published

2022

26. WRF-LES Simulation of the Boundary Layer Turbulent Processes during the BLLAST Campaign

Author

Mireia Udina, Àlex Montornès, Pau Casso, Branko Kosović, and Joan Bech

Subjects

large eddy simulation, verification, turbulence, WRF, Meteorology. Climatology, QC851-999

Abstract

A real case long-term nested large eddy simulation (LES) of 25-day duration is performed using the WRF-LES modelling system, with a maximum horizontal grid resolution of 111 m, in order to explore the ability of the model to reproduce the turbulence magnitudes within the first tens of metres of the boundary layer. Sonic anemometer measurements from a 60-m tower installed during the Boundary Layer Late Afternoon and Sunset Turbulence (BLLAST) field campaign are used for verification, which is focused on the turbulent magnitudes in order to assess the success and limitations in resolving turbulent flow characteristics. The mesoscale and LES simulations reproduce the wind speed and direction fairly well, but only LES is able to reproduce the energy of eddies with lifetimes shorter than a few hours. The turbulent kinetic energy in LES simulation is generally underestimated during the daytime, mainly due to a vertical velocity standard deviation that is too low. The turbulent heat flux is misrepresented in the model, probably due to the inaccuracy of the sub-grid scheme.

Published

2020

27. Combining Artificial Intelligence with Physics-Based Methods for Probabilistic Renewable Energy Forecasting

Author

Sue Ellen Haupt, Tyler C. McCandless, Susan Dettling, Stefano Alessandrini, Jared A. Lee, Seth Linden, William Petzke, Thomas Brummet, Nhi Nguyen, Branko Kosović, Gerry Wiener, Tahani Hussain, and Majed Al-Rasheedi

Subjects

wind energy, solar energy, renewable energy forecasting, artificial intelligence, machine learning, Technology

Abstract

A modern renewable energy forecasting system blends physical models with artificial intelligence to aid in system operation and grid integration. This paper describes such a system being developed for the Shagaya Renewable Energy Park, which is being developed by the State of Kuwait. The park contains wind turbines, photovoltaic panels, and concentrated solar renewable energy technologies with storage capabilities. The fully operational Kuwait Renewable Energy Prediction System (KREPS) employs artificial intelligence (AI) in multiple portions of the forecasting structure and processes, both for short-range forecasting (i.e., the next six hours) as well as for forecasts several days out. These AI methods work synergistically with the dynamical/physical models employed. This paper briefly describes the methodology used for each of the AI methods, how they are blended, and provides a preliminary assessment of their relative value to the prediction system. Each operational AI component adds value to the system. KREPS is an example of a fully integrated state-of-the-science forecasting system for renewable energy.

Published

2020

28. A Large-Eddy Simulation Study of the Influence of Subsidence on the Stably Stratified Atmospheric Boundary Layer

Author

Branko Kosovic and Jeffrey D. Mirocha

Subjects

Momentum (technical analysis), Atmospheric Science, Richardson number, Meteorology, Planetary boundary layer, Subsidence (atmosphere), Atmospheric sciences, Snow, Stable boundary layer, Subsidence, Physics::Geophysics, Meteorology/Climatology, Boundary layer, Large-eddy simulation, Arctic Ocean, Earth Sciences, Potential temperature, Atmospheric Protection/Air Quality Control/Air Pollution, Geology, Large eddy simulation

Abstract

The influence of the large-scale subsidence rate, S, on the stably stratified atmospheric boundary layer (ABL) over the Arctic Ocean snow/ice pack during clear-sky, winter conditions is investigated using a large-eddy simulation model. Simulations of two 24-h periods are conducted while varying S between 0, 0.001 and 0.002 ms−1, and the resulting quasi-equilibrium ABL structures and evolutions are examined. Simulations conducted with S = 0 yield a boundary layer that is deeper, more strongly mixed and cools more rapidly than the observations. Simulations conducted with S > 0 yield improved agreement with the observations in the ABL height, potential temperature gradients and bulk heating rates. We also demonstrate that S > 0 limits the continuous growth of the ABL observed during quasi-steady conditions, leading to the formation of a nearly steady ABL of approximately uniform depth and temperature. Subsidence reduces the magnitudes of the stresses, as well as the implied eddy-diffusivity coefficients for momentum and heat, while increasing the vertical heat fluxes considerably. Subsidence is also observed to increases the Richardson number to values in excess of unity well below the ABL top.

29. Results of the GABLS3 diurnal-cycle benchmark for wind energy applications

Author

Javier Sanz Rodrigo, Dries Allaerts, Matias Avila, Jordi Barcons, Dalivor Cavar, Roberto Aurelio Chávez Arroyo, Matthiew Churchfield, Branko Kosovic, Julie K Lundquist, Johan Meyers, Domingo Muñoz Esparza, José M L M Palma, Jessica M Tomaszewski, Niels Troldborg, Paul van der Laan, and Carlos Veiga Rodrigues

Subjects

RANS, LES, ABL, Wakebench, 7. Clean energy, low-level jet

Abstract

Presentation at the Wake Conference, Visby, 1 June2017. The associated paper can be found at: http://iopscience.iop.org/article/10.1088/1742-6596/854/1/012037 Abstract We present results of the GABLS3 model intercomparison benchmark revisited forwind energy applications. The case consists of a diurnal cycle, measured at the 200-m tallCabauw tower in the Netherlands, including a nocturnal low-level jet. The benchmark includesa sensitivity analysis of WRF simulations using two input meteorological databases and fiveplanetary boundary-layer schemes. A reference set of mesoscale tendencies is used to drivemicroscale simulations using RANS k-ε and LES turbulence models. The validation is basedon rotor-based quantities of interest. Cycle-integrated mean absolute errors are used to quantify model performance. The results of the benchmark are used to discuss input uncertainties frommesoscale modelling, different meso-micro coupling strategies (online vs offline) andconsistency between RANS and LES codes when dealing with boundary-layer mean flowquantities. Overall, all the microscale simulations produce a consistent coupling withmesoscale forcings.