Articles citing this paper
Mapping the daily progression of large wildland fires using MODIS active fire data
Sander Veraverbeke A B D , Fernando Sedano B C , Simon J. Hook A , James T. Randerson B , Yufang Jin B and Brendan M. Rogers B
+ Author Affiliations
- Author Affiliations
A Jet Propulsion Laboratory (NASA), California Institute of Technology, 4800 Oak Grove Drive, Pasadena, CA 91109, USA.
B Department of Earth System Science, University of California, 2224 Croul Hall, Irvine, CA 92697, USA.
C Department of Geograpical Sciences, University of Maryland, 2181 LeFrak Hall, College Park, MD 20742, USA.
D Corresponding author. Email: sander.veraverbeke@uci.edu
International Journal of Wildland Fire 23(5) 655-667 https://doi.org/10.1071/WF13015
Submitted: 30 January 2013 Accepted: 12 November 2013 Published: 7 March 2014
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Infrared Remote Sensing and Instrumentation XXIII (2015)
Future increases in lightning ignition efficiency and wildfire occurrence expected from drier fuels in boreal forest ecosystems of western North America
Hessilt Thomas D,
Abatzoglou John T,
Chen Yang,
Randerson James T,
Scholten Rebecca C,
van der Werf Guido, Veraverbeke Sander
Environmental Research Letters. 2022 17(5). p.054008
Wildfire Detection Probability of MODIS Fire Products under the Constraint of Environmental Factors: A Study Based on Confirmed Ground Wildfire Records
Ying Lingxiao,
Shen Zehao,
Yang Mingzheng, Piao Shilong
Remote Sensing. 2019 11(24). p.3031
An Interactive Data-Driven HPC System for Forecasting Weather, Wildland Fire, and Smoke
2019 IEEE/ACM HPC for Urgent Decision Making (UrgentHPC) (2019)
The Portuguese Large Wildfire Spread database (PT-FireSprd)
Benali Akli,
Guiomar Nuno,
Gonçalves Hugo,
Mota Bernardo,
Silva Fábio,
Fernandes Paulo M.,
Mota Carlos,
Penha Alexandre,
Santos João,
Pereira José M. C., Sá Ana C. L.
Earth System Science Data. 2023 15(8). p.3791
Disentangling the role of prefire vegetation vs. burning conditions on fire severity in a large forest fire in SE Spain
Viedma O.,
Chico F.,
Fernández J.J.,
Madrigal C.,
Safford H.D., Moreno J.M.
Remote Sensing of Environment. 2020 247 p.111891
Estimating wildfire growth from noisy and incomplete incident data using a state space model
Podschwit Harry,
Guttorp Peter,
Larkin Narasimhan, Steel E. Ashley
Environmental and Ecological Statistics. 2018 25(3). p.325
Machine Learning Estimation of Fire Arrival Time from Level-2 Active Fires Satellite Data
Farguell Angel,
Mandel Jan,
Haley James,
Mallia Derek V.,
Kochanski Adam, Hilburn Kyle
Remote Sensing. 2021 13(11). p.2203
Evaluating fire growth simulations using satellite active fire data
Sá Ana C.L.,
Benali Akli,
Fernandes Paulo M.,
Pinto Renata M.S.,
Trigo Ricardo M.,
Salis Michele,
Russo Ana,
Jerez Sonia,
Soares Pedro M.M.,
Schroeder Wilfrid, Pereira José M.C.
Remote Sensing of Environment. 2017 190 p.302
A landscape model of variable social-ecological fire regimes
Scheller Robert,
Kretchun Alec,
Hawbaker Todd J., Henne Paul D.
Ecological Modelling. 2019 401 p.85
UAV Assisted Spatiotemporal Analysis and Management of Bushfires: A Case Study of the 2020 Victorian Bushfires
Munawar Hafiz Suliman,
Ullah Fahim,
Khan Sara Imran,
Qadir Zakria, Qayyum Siddra
Fire. 2021 4(3). p.40
Predicting Potential Fire Severity Using Vegetation, Topography and Surface Moisture Availability in a Eurasian Boreal Forest Landscape
Fang Lei,
Yang Jian,
White Megan, Liu Zhihua
Forests. 2018 9(3). p.130
Grazing and wildfire effects on small mammals inhabiting montane meadows
Horncastle Valerie J.,
Chambers Carol L., Dickson Brett G.
The Journal of Wildlife Management. 2019 83(3). p.534
Spatiotemporal Analysis of Forest Fires in China from 2012 to 2021 Based on Visible Infrared Imaging Radiometer Suite (VIIRS) Active Fires
Dong Bing,
Li Hongwei,
Xu Jian,
Han Chaolin, Zhao Shan
Sustainability. 2023 15(12). p.9532
Constructing a Comprehensive National Wildfire Database from Incomplete Sources: Israel as a Case Study
Guk Edna,
Bar-Massada Avi, Levin Noam
Fire. 2023 6(4). p.131
Multi-scale influence of vapor pressure deficit on fire ignition and spread in boreal forest ecosystems
Sedano F., Randerson J. T.
Biogeosciences. 2014 11(14). p.3739
Airborne Optical and Thermal Remote Sensing for Wildfire Detection and Monitoring
Allison Robert,
Johnston Joshua,
Craig Gregory, Jennings Sion
Sensors. 2016 16(8). p.1310
Cloud-Based Remote Sensing with Google Earth Engine (2024)
Social Science/Natural Science Perspectives on Wildfire and Climate Change
Ayres Andrew,
Degolia Alexander,
Fienup Matthew,
Kim Yunyeol,
Sainz Jade,
Urbisci Laura,
Viana Daniel,
Wesolowski Graham,
Plantinga Andrew J., Tague Christina
Geography Compass. 2016 10(2). p.67
Overwintering fires in boreal forests
Scholten Rebecca C.,
Jandt Randi,
Miller Eric A.,
Rogers Brendan M., Veraverbeke Sander
Nature. 2021 593(7859). p.399
Daily burned area and carbon emissions from boreal fires in Alaska
Veraverbeke S.,
Rogers B. M., Randerson J. T.
Biogeosciences. 2015 12(11). p.3579
Generating intra-year metrics of wildfire progression using multiple open-access satellite data streams
Crowley Morgan A.,
Cardille Jeffrey A.,
White Joanne C., Wulder Michael A.
Remote Sensing of Environment. 2019 232 p.111295
Unveiling the Factors Responsible for Australia’s Black Summer Fires of 2019/2020
Levin Noam,
Yebra Marta, Phinn Stuart
Fire. 2021 4(3). p.58
Active Fire Dynamics in the Amazon: New Perspectives From High‐Resolution Satellite Observations
Xu Wenxuan,
Liu Yongxue,
Veraverbeke Sander,
Wu Wei,
Dong Yanzhu, Lu Wanyun
Geophysical Research Letters. 2021 48(20).
Evaluation of Fire Products Using Spatio-Temporal Clustering Method
IGARSS 2022 - 2022 IEEE International Geoscience and Remote Sensing Symposium (2022)
Global fire emissions estimates during 1997–2016
van der Werf Guido R.,
Randerson James T.,
Giglio Louis,
van Leeuwen Thijs T.,
Chen Yang,
Rogers Brendan M.,
Mu Mingquan,
van Marle Margreet J. E.,
Morton Douglas C.,
Collatz G. James,
Yokelson Robert J., Kasibhatla Prasad S.
Earth System Science Data. 2017 9(2). p.697
Synoptic weather patterns during fire spread events in Siberia
Tomshin Oleg, Solovyev Vladimir
Science of The Total Environment. 2024 921 p.171205
Fine‐scale spatial climate variation and drought mediate the likelihood of reburning
Parks Sean A.,
Parisien Marc‐André,
Miller Carol,
Holsinger Lisa M., Baggett Larry Scott
Ecological Applications. 2018 28(2). p.573
Automated location of active fire perimeters in aerial infrared imaging using unsupervised edge detectors
Valero M. M.,
Rios O.,
Pastor E., Planas E.
International Journal of Wildland Fire. 2018 27(4). p.241
Satellite-based long-term spatiotemporal trends of wildfire in the Himalayan vegetation
Mamgain Shailja,
Roy Arijit,
Karnatak Harish Chandra, Chauhan Prakash
Natural Hazards. 2023 116(3). p.3779
Multiple remote sensing data sources to assess spatio-temporal patterns of fire incidence over Campos Amazônicos Savanna Vegetation Enclave (Brazilian Amazon)
Alves Daniel Borini, Pérez-Cabello Fernando
Science of The Total Environment. 2017 601-602 p.142
What Drives Low-Severity Fire in the Southwestern USA?
Parks Sean,
Dobrowski Solomon, Panunto Matthew
Forests. 2018 9(4). p.165
Deciphering the impact of uncertainty on the accuracy of large wildfire spread simulations
Benali Akli,
Ervilha Ana R.,
Sá Ana C.L.,
Fernandes Paulo M.,
Pinto Renata M.S.,
Trigo Ricardo M., Pereira José M.C.
Science of The Total Environment. 2016 569-570 p.73
A Protocol for Collecting Burned Area Time Series Cross-Check Data
Podschwit Harry R.,
Potter Brian, Larkin Narasimhan K.
Fire. 2022 5(5). p.153
Determining Fire Dates and Locating Ignition Points With Satellite Data
Benali Akli,
Russo Ana,
Sá Ana,
Pinto Renata,
Price Owen,
Koutsias Nikos, Pereira José
Remote Sensing. 2016 8(4). p.326
Real-time autonomous wildfire monitoring and georeferencing using rapidly deployable mobile units
Perez-Mato Javier,
Arana Victor, Cabrera-Almeida Francisco
IEEE Aerospace and Electronic Systems Magazine. 2016 31(2). p.6
Extreme Weather Forecasting (2023)
The Global Fire Atlas of individual fire size, duration, speed and direction
Andela Niels,
Morton Douglas C.,
Giglio Louis,
Paugam Ronan,
Chen Yang,
Hantson Stijn,
van der Werf Guido R., Randerson James T.
Earth System Science Data. 2019 11(2). p.529
Modelling hourly spatio-temporal PM2.5 concentration in wildfire scenarios using dynamic linear models
Sánchez-Balseca Joseph, Pérez-Foguet Agustí
Atmospheric Research. 2020 242 p.104999
Satellite remote sensing of ecosystem functions: opportunities, challenges and way forward
Pettorelli Nathalie,
Schulte to Bühne Henrike,
Tulloch Ayesha,
Dubois Grégoire,
Macinnis‐Ng Cate,
Queirós Ana M.,
Keith David A.,
Wegmann Martin,
Schrodt Franziska,
Stellmes Marion,
Sonnenschein Ruth,
Geller Gary N.,
Roy Shovonlal,
Somers Ben,
Murray Nicholas,
Bland Lucie,
Geijzendorffer Ilse,
Kerr Jeremy T.,
Broszeit Stefanie,
Leitão Pedro J.,
Duncan Clare,
El Serafy Ghada,
He Kate S.,
Blanchard Julia L.,
Lucas Richard,
Mairota Paola,
Webb Thomas J.,
Nicholson Emily,
Rowcliffe Marcus, Disney Mat
Remote Sensing in Ecology and Conservation. 2018 4(2). p.71
Advances in remote sensing and GIS applications in support of forest fire management
Gitas Ioannis Z.,
San-Miguel-Ayanz Jesús,
Chuvieco Emilio, Camia Andrea
International Journal of Wildland Fire. 2014 23(5). p.603
Fire Behavior Monitoring and Assessment in California with Multi-sensor Satellite Observations
IGARSS 2019 - 2019 IEEE International Geoscience and Remote Sensing Symposium (2019)
Near Real-Time Automated Early Mapping of the Perimeter of Large Forest Fires from the Aggregation of VIIRS and MODIS Active Fires in Mexico
Briones-Herrera Carlos Ivan,
Vega-Nieva Daniel José,
Monjarás-Vega Norma Angélica,
Briseño-Reyes Jaime,
López-Serrano Pablito Marcelo,
Corral-Rivas José Javier,
Alvarado-Celestino Ernesto,
Arellano-Pérez Stéfano,
Álvarez-González Juan Gabriel,
Ruiz-González Ana Daría,
Jolly William Mathew, Parks Sean A.
Remote Sensing. 2020 12(12). p.2061
A comprehensive characterization of MODIS daily burned area mapping accuracy across fire sizes in tropical savannas
Campagnolo M.L.,
Libonati R.,
Rodrigues J.A., Pereira J.M.C.
Remote Sensing of Environment. 2021 252 p.112115
Probabilistic fire spread forecast as a management tool in an operational setting
Pinto Renata M.S.,
Benali Akli,
Sá Ana C. L.,
Fernandes Paulo M.,
Soares Pedro M. M.,
Cardoso Rita M.,
Trigo Ricardo M., Pereira José M. C.
SpringerPlus. 2016 5(1).
Can We Go Beyond Burned Area in the Assessment of Global Remote Sensing Products with Fire Patch Metrics?
Nogueira Joana,
Ruffault Julien,
Chuvieco Emilio, Mouillot Florent
Remote Sensing. 2016 9(1). p.7
Satellite-Based Fire Progression Mapping: A Comprehensive Assessment for Large Fires in Northern California
Scaduto Erica,
Chen Bin, Jin Yufang
IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing. 2020 13 p.5102
Fire spread predictions: Sweeping uncertainty under the rug
Benali Akli,
Sá Ana C.L.,
Ervilha Ana R.,
Trigo Ricardo M.,
Fernandes Paulo M., Pereira José M.C.
Science of The Total Environment. 2017 592 p.187
Consistent, high-accuracy mapping of daily and sub-daily wildfire growth with satellite observations
McClure Crystal D.,
Pavlovic Nathan R.,
Huang ShihMing,
Chaveste Melissa, Wang Ningxin
International Journal of Wildland Fire. 2023 32(5). p.694
Observed Fire Behaviour Products from the Wildfiresat Mission
IGARSS 2023 - 2023 IEEE International Geoscience and Remote Sensing Symposium (2023)
Spatio-temporal patterns of wildfires in Siberia during 2001–2020
Tomshin Oleg, Solovyev Vladimir
Geocarto International. 2022 37(25). p.7339
Modelling Hazardous Reduction Burnings and Bushfire Emission in Air Quality Model and Their Impacts on Health in the Greater Metropolitan Region of Sydney
Nguyen Hiep Duc,
Trieu Toan,
Cope Martin,
Azzi Merched, Morgan Geoffrey
Environmental Modeling & Assessment. 2020 25(5). p.705
Lightning as a major driver of recent large fire years in North American boreal forests
Veraverbeke Sander,
Rogers Brendan M.,
Goulden Mike L.,
Jandt Randi R.,
Miller Charles E.,
Wiggins Elizabeth B., Randerson James T.
Nature Climate Change. 2017 7(7). p.529
Time series of high-resolution images enhances efforts to monitor post-fire condition and recovery, Waldo Canyon fire, Colorado, USA
Vanderhoof Melanie K.,
Burt Clifton, Hawbaker Todd J.
International Journal of Wildland Fire. 2018 27(10). p.699
Overwintering fires rising in eastern Siberia
Xu Wenxuan,
Scholten Rebecca C,
Hessilt Thomas D,
Liu Yongxue, Veraverbeke Sander
Environmental Research Letters. 2022 17(4). p.045005
Fuel-Specific Aggregation of Active Fire Detections for Rapid Mapping of Forest Fire Perimeters in Mexico
Briones-Herrera Carlos Ivan,
Vega-Nieva Daniel José,
Briseño-Reyes Jaime,
Monjarás-Vega Norma Angélica,
López-Serrano Pablito Marcelo,
Corral-Rivas José Javier,
Alvarado Ernesto,
Arellano-Pérez Stéfano,
Jardel Peláez Enrique J.,
Pérez Salicrup Diego Rafael, Jolly William Matthew
Forests. 2022 13(1). p.124
Performance of Three MODIS Fire Products (MCD45A1, MCD64A1, MCD14ML), and ESA Fire_CCI in a Mountainous Area of Northwest Yunnan, China, Characterized by Frequent Small Fires
Fornacca Davide,
Ren Guopeng, Xiao Wen
Remote Sensing. 2017 9(11). p.1131
Tracking and classifying Amazon fire events in near real time
Andela Niels,
Morton Douglas C.,
Schroeder Wilfrid,
Chen Yang,
Brando Paulo M., Randerson James T.
Science Advances. 2022 8(30).
A Suitable Model for Spatiotemporal Particulate Matter Concentration Prediction in Rural and Urban Landscapes, Thailand
Tongprasert Pirada, Ongsomwang Suwit
Atmosphere. 2022 13(6). p.904
High-severity fire: evaluating its key drivers and mapping its probability across western US forests
Parks Sean A,
Holsinger Lisa M,
Panunto Matthew H,
Jolly W Matt,
Dobrowski Solomon Z, Dillon Gregory K
Environmental Research Letters. 2018 13(4). p.044037
Remote Sensing Active Fire Detection Tools Support Growth Reconstruction for Large Boreal Wildfires
Schiks Tom J.,
Wotton B. Mike, Martell David L.
Fire. 2024 7(1). p.26
Evaluation of Four Satellite-Derived Fire Products in the Fire-Prone, Cloudy, and Mountainous Area Over Subtropical China
Jiao Miao,
Quan Xingwen, Yao Jinsong
IEEE Geoscience and Remote Sensing Letters. 2022 19 p.1
Characterizing the rate of spread of large wildfires in emerging fire environments of northwestern Europe using Visible Infrared Imaging Radiometer Suite active fire data
Cardíl Adrián,
Tapia Victor M.,
Monedero Santiago,
Quiñones Tomás,
Little Kerryn,
Stoof Cathelijne R.,
Ramirez Joaquín, de-Miguel Sergio
Natural Hazards and Earth System Sciences. 2023 23(1). p.361
A remote sensing-based approach to estimating the fire spread rate parameter for individual burn patch extraction
Humber Michael,
Zubkova Maria, Giglio Louis
International Journal of Remote Sensing. 2022 43(2). p.649
A global database on holdover time of lightning-ignited wildfires
Moris Jose V.,
Álvarez-Álvarez Pedro,
Conedera Marco,
Dorph Annalie,
Hessilt Thomas D.,
Hunt Hugh G. P.,
Libonati Renata,
Menezes Lucas S.,
Müller Mortimer M.,
Pérez-Invernón Francisco J.,
Pezzatti Gianni B.,
Pineda Nicolau,
Scholten Rebecca C.,
Veraverbeke Sander,
Wotton B. Mike, Ascoli Davide
Earth System Science Data. 2023 15(3). p.1151
Assessing and reinitializing wildland fire simulations through satellite active fire data
Cardil Adrián,
Monedero Santiago,
Ramírez Joaquin, Silva Carlos Alberto
Journal of Environmental Management. 2019 231 p.996
