Your search keyword '"Cardil, Adrián"' showing total 25 results

1. Fire impacts on the biology of stream ecosystems: A synthesis of current knowledge to guide future research and integrated fire management.

Author

Erdozain, Maitane, Cardil, Adrián, and de‐Miguel, Sergio

Subjects

PRESCRIBED burning, RIPARIAN forests, TEMPERATE forests, ECOSYSTEM services, BIOMASS, FIRE management, BIOINDICATORS

Abstract

Freshwater ecosystems host disproportionately high biodiversity and provide unique ecosystem services, yet they are being degraded at an alarming rate. Fires, which are becoming increasingly frequent and intense due to global change, can affect these ecosystems in many ways, but this relationship is not fully understood. We conducted a systematic review to characterize the literature on the effects of fires on stream ecosystems and found that (1) abiotic indicators were more commonly investigated than biotic ones, (2) most previous research was conducted in North America and in the temperate evergreen forest biome, (3) following a control‐impact (CI) or before‐after (BA) design, (4) predominantly assessing wildfires as opposed to prescribed fires, (5) in small headwater streams, and (6) with a focus on structural and not functional biological indicators. After quantitatively analyzing previous research, we detected great variability in responses, with increases, decreases, and no changes being reported for most indicators (e.g., macroinvertebrate richness, fish density, algal biomass, and leaf decomposition). We shed light on these seemingly contradicting results by showing that the presence of extreme hydrological post‐fire events, the time lag between fire and sampling, and whether the riparian forest burned or not influenced the outcome of previous research. Results suggest that although wildfires and the following hydrological events can have dramatic impacts in the short term, most biological endpoints recover within 5–10 years, and that detrimental effects are minimal in the case of prescribed fires. We also detected that no effects were more often reported by BACI studies than by CI or BA studies, raising the question of whether this research field may be biased by the inherent limitations of CI and BA designs. Finally, we make recommendations to help advance this field of research and guide future integrated fire management that includes the protection of freshwater ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

2. Performance of operational fire spread models in California.

Author

Cardil, Adrián, Monedero, Santiago, SeLegue, Phillip, Navarrete, Miguel Ángel, de-Miguel, Sergio, Purdy, Scott, Marshall, Geoff, Chavez, Tim, Allison, Kristen, Quilez, Raúl, Ortega, Macarena, Silva, Carlos A., and Ramirez, Joaquin

Subjects

JOB performance, DATABASES, DATA quality, FIRE management, TIME management

Abstract

Background: Wildfire simulators allow estimating fire spread and behaviour in complex environments, supporting planning and analysis of incidents in real time. However, uncertainty derived from input data quality and model inherent inaccuracies may undermine the utility of such predictions. Aims: We assessed the performance of fire spread models for initial attack incidents used in California through the analysis of the rate of spread (ROS) of 1853 wildfires. Methods: We retrieved observed fire growth from the FireGuard (FG) database, ran an automatic simulation with Wildfire Analyst Enterprise and assessed the accuracy of the simulations by comparing observed and predicted ROS with well-known error and bias metrics, analysing the main factors influencing accuracy. Key results: The model errors and biases were reasonable for simulations performed automatically. We identified environmental variables that may bias ROS predictions, especially in timber areas where some fuel models underestimated ROS. Conclusions: The fire spread models' performance for California is in line with studies developed in other regions and the models are accurate enough to be used in real time to assess initial attack fires. Implications: This work allows users to better understand the performance of fire spread models in operational environments and opens new research lines to further improve the performance of current operational models. This work analyses the performance of automated fire spread models used in California operationally to predict initial fire spread across landscapes. The models are accurate enough to be used in real-time operations to support preparedness and response actions, although new enhancements are desirable, especially to simulate fires in timber areas. [ABSTRACT FROM AUTHOR]

Published

2023

3. Climate teleconnections modulate global burned area.

Author

Cardil, Adrián, Rodrigues, Marcos, Tapia, Mario, Barbero, Renaud, Ramírez, Joaquin, Stoof, Cathelijne R., Silva, Carlos Alberto, Mohan, Midhun, and de-Miguel, Sergio

Subjects

VEGETATION patterns, FIRE management, WEATHER, BIOMES, CONTINENTS, POLICY sciences, TELECONNECTIONS (Climatology), FOREST fires

Abstract

Climate teleconnections (CT) remotely influence weather conditions in many regions on Earth, entailing changes in primary drivers of fire activity such as vegetation biomass accumulation and moisture. We reveal significant relationships between the main global CTs and burned area that vary across and within continents and biomes according to both synchronous and lagged signals, and marked regional patterns. Overall, CTs modulate 52.9% of global burned area, the Tropical North Atlantic mode being the most relevant CT. Here, we summarized the CT-fire relationships into a set of six global CT domains that are discussed by continent, considering the underlying mechanisms relating weather patterns and vegetation types with burned area across the different world's biomes. Our findings highlight the regional CT-fire relationships worldwide, aiming to further support fire management and policy-making. Here the authors find that climate teleconnections modulate ~53 % of the global burned area with both synchronous and lagged signals, and marked regional patterns, with the Tropical North Atlantic mode being the most relevant. [ABSTRACT FROM AUTHOR]

Published

2023

4. Analyzing Canopy Height Patterns and Environmental Landscape Drivers in Tropical Forests Using NASA's GEDI Spaceborne LiDAR.

Author

Adrah, Esmaeel, Wan Mohd Jaafar, Wan Shafrina, Omar, Hamdan, Bajaj, Shaurya, Leite, Rodrigo Vieira, Mazlan, Siti Munirah, Silva, Carlos Alberto, Chel Gee Ooi, Maggie, Mohd Said, Mohd Nizam, Abdul Maulud, Khairul Nizam, Cardil, Adrián, and Mohan, Midhun

Subjects

TROPICAL forests, SPACE-based radar, BOOSTING algorithms, FOREST management, FOREST monitoring, MOUNTAIN forests, LIDAR, WATER supply

Abstract

Canopy height is a fundamental parameter for determining forest ecosystem functions such as biodiversity and above-ground biomass. Previous studies examining the underlying patterns of the complex relationship between canopy height and its environmental and climatic determinants suffered from the scarcity of accurate canopy height measurements at large scales. NASA's mission, the Global Ecosystem Dynamic Investigation (GEDI), has provided sampled observations of the forest vertical structure at near global scale since late 2018. The availability of such unprecedented measurements allows for examining the vertical structure of vegetation spatially and temporally. Herein, we explore the most influential climatic and environmental drivers of the canopy height in tropical forests. We examined different resampling resolutions of GEDI-based canopy height to approximate maximum canopy height over tropical forests across all of Malaysia. Moreover, we attempted to interpret the dynamics underlining the bivariate and multivariate relationships between canopy height and its climatic and topographic predictors including world climate data and topographic data. The approaches to analyzing these interactions included machine learning algorithms, namely, generalized linear regression, random forest and extreme gradient boosting with tree and Dart implementations. Water availability, represented as the difference between precipitation and potential evapotranspiration, annual mean temperature and elevation gradients were found to be the most influential determinants of canopy height in Malaysia's tropical forest landscape. The patterns observed are in line with the reported global patterns and support the hydraulic limitation hypothesis and the previously reported negative trend for excessive water supply. Nevertheless, different breaking points for excessive water supply and elevation were identified in this study, and the canopy height relationship with water availability observed to be less significant for the mountainous forest on altitudes higher than 1000 m. This study provides insights into the influential factors of tree height and helps with better comprehending the variation in canopy height in tropical forests based on GEDI measurements, thereby supporting the development and interpretation of ecosystem modeling, forest management practices and monitoring forest response to climatic changes in montane forests. [ABSTRACT FROM AUTHOR]

Published

2022

5. Do climate teleconnections modulate wildfire-prone conditions over the Iberian Peninsula?

Author

Rodrigues, Marcos, Peńa-Angulo, Dhais, Russo, Ana, Zúńiga-Antón, María, and Cardil, Adrián

Published

2021

6. Recent deforestation drove the spike in Amazonian fires.

Author

Cardil, Adrián, de-Miguel, Sergio, Silva, Carlos A, Reich, Peter B, Calkin, David, Brancalion, Pedro H S, Vibrans, Alexander C, Gamarra, Javier G P, Zhou, M, Pijanowski, Bryan C, Hui, Cang, Crowther, Thomas W, Hérault, Bruno, Piotto, Daniel, Salas-Eljatib, Christian, Broadbent, Eben North, Zambrano, Angelica M Almeyda, Picard, Nicolas, Aragăo, Luiz E O C, and Bastin, Jean-Francois

Published

2020

7. Climate teleconnections synchronize Picea glauca masting and fire disturbance: Evidence for a fire‐related form of environmental prediction.

Author

Ascoli, Davide, Hacket‐Pain, Andrew, LaMontagne, Jalene M., Cardil, Adrián, Conedera, Marco, Maringer, Janet, Motta, Renzo, Pearse, Ian S., Vacchiano, Giorgio, and Bellingham, Peter

Subjects

TELECONNECTIONS (Climatology), FIRE, WHITE spruce, DROUGHT management, ATLANTIC multidecadal oscillation, FORECASTING, CLIMATOLOGY, TAIGAS

Abstract

Copyright of Journal of Ecology is the property of Wiley-Blackwell and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2020

8. A new era in forest restoration monitoring.

Author

de Almeida, Danilo R. A., Stark, Scott C., Valbuena, Ruben, Broadbent, Eben N., Silva, Thiago S. F., de Resende, Angelica F., Ferreira, Matheus P., Cardil, Adrián, Silva, Carlos A., Amazonas, Nino, Zambrano, Angelica M. A., and Brancalion, Pedro H. S.

Subjects

FOREST monitoring, RESTORATION ecology, ECOLOGICAL restoration monitoring, FOREST restoration, REMOTE sensing, VEGETATION monitoring, SCIENTISTS

Abstract

Monitoring ecological restoration has been historically dependent on traditional inventory methods based on detailed information obtained from field plots. New paradigms are now needed to successfully achieve restoration as a large‐scale, long‐lasting transformative process. Fortunately, advances in technology now allow for unprecedented shifts in the way restoration has been planned, implemented, and monitored. Here, we describe our vision on how the use of new technologies by a new generation of restoration ecologists may revolutionize restoration monitoring in the coming years. The success of the many ambitious restoration programs planned for the coming decade will rely on effective monitoring, which is an essential component of adaptive management and accountability. The development of new remote sensing approaches and their application to a restoration context open new avenues for expanding our capacity to assess restoration performance over unprecedented spatial and temporal scales. A new generation of scientists, which have a background in remote sensing but are getting more and more involved with restoration, will certainly play a key role for making large‐scale restoration monitoring a viable human endeavor in the coming decade—the United Nations' decade on ecosystem restoration. [ABSTRACT FROM AUTHOR]

Published

2020

9. Quantifying pine processionary moth defoliation in a pine-oak mixed forest using unmanned aerial systems and multispectral imagery.

Author

Cardil, Adrián, Otsu, Kaori, Pla, Magda, Silva, Carlos Alberto, and Brotons, Lluis

Subjects

CONIFERS, PINACEAE, MIXED forests

Abstract

Pine processionary moth (PPM) feeds on conifer foliage and periodically result in outbreaks leading to large scale defoliation, causing decreased tree growth, vitality and tree reproduction capacity. Multispectral high-resolution imagery acquired from a UAS platform was successfully used to assess pest tree damage at the tree level in a pine-oak mixed forest. We generated point clouds and multispectral orthomosaics from UAS through photogrammetric processes. These were used to automatically delineate individual tree crowns and calculate vegetation indices such as the normalized difference vegetation index (NDVI) and excess green index (ExG) to objectively quantify defoliation of trees previously identified. Overall, our research suggests that UAS imagery and its derived products enable robust estimation of tree crowns with acceptable accuracy and the assessment of tree defoliation by classifying trees along a gradient from completely defoliated to non-defoliated automatically with 81.8% overall accuracy. The promising results presented in this work should inspire further research and applications involving a combination of methods allowing the scaling up of the results on multispectral imagery by integrating satellite remote sensing information in the assessments over large spatial scales. [ABSTRACT FROM AUTHOR]

Published

2019

10. Analysis of forest fire fatalities in Southern Europe: Spain, Portugal, Greece and Sardinia (Italy).

Author

Molina-Terrén, Domingo M., Xanthopoulos, Gavriil, Diakakis, Michalis, Ribeiro, Luis, Caballero, David, Delogu, Giuseppe M., Viegas, Domingos X., Silva, Carlos A., and Cardil, Adrián

Subjects

WILDFIRES, WILDLAND-urban interface, FOREST fires, FIRE victims

Abstract

Wildfire fatalities remain a significant problem in Mediterranean Europe. Although there is a strong inter-annual variability with regard to their number, repeated tragic accidents remind us of this grim occurrence, despite the increasing firefighting capacity aimed to improve human safety. In this paper, we present an analysis of the 865 fatalities caused by wildfires in the 1945–2016 period. Data originating from national databases were merged, contextual and weather factors related to the accidents that caused these deaths were documented and analysed to explore probable relationships with the number and type of fatalities. Results show a major rise of fatalities in late 1970s in the four regions of Greece, Sardinia (Italy), Spain and Portugal. Fatalities present a strong seasonality in summer months, as expected. Overall, Spain has the highest absolute numbers of fatalities; however, normalisations by population, and burned and forest area show that annual number of fatalities is comparatively smaller. Certain other factors showed correlation with mortality. Civilians were the most affected group in Greece (65%) and Sardinia (58%), but not in Spain and Portugal. Findings indicate that an in-depth revision of fire-management policies and practices is required, with emphasis on prevention planning in urban areas, and better training of the firefighting resources. Wildfire fatalities remain a significant problem in Mediterranean Europe. There is a strong inter-annual variability in losses. Repeated tragic accidents remind us of this grim reality, regardless of the increasing firefighting capacity aiming to improve human safety. This paper presents an analysis of 865 fatalities over the period 1945–2016. [ABSTRACT FROM AUTHOR]

Published

2019

11. Assessing Pine Processionary Moth Defoliation Using Unmanned Aerial Systems.

Author

Cardil, Adrián, Brotons, Lluis, and Vepakomma, Udayalakshmi

Subjects

THAUMETOPOEA, DRONE aircraft, PEST control, DEFOLIATION, MOTH flies

Abstract

Pine processionary moth (PPM) is one of the most destructive insect defoliators in the Mediterranean for many conifers, causing losses of growth, vitality and eventually the death of trees during outbreaks. There is a growing need for cost-effective monitoring of the temporal and spatial impacts of PPM in forest ecology to better assess outbreak spread patterns and provide guidance on the development of measures targeting the negative impacts of the species on forests, industry and human health. Remote sensing technology mounted on unmanned aerial systems (UASs) with high-resolution image processing has been proposed to assess insect outbreak impacts at local and forest stand levels. Here, we used UAS-acquired RGB imagery in two pine sites to quantify defoliation at the tree-level and to verify the accuracy of the estimates. Our results allowed the identification of healthy, infested and completely defoliated trees and suggested that pine defoliation estimates using UASs are robust and allow high-accuracy (79%) field-based infestation indexes to be derived that are comparable to those used by forest technicians. When compared to current field-based methods, our approach provides PPM impact assessments with an efficient data acquisition method in terms of time and staff, allowing the quantitative estimation of defoliation at tree-level scale. Furthermore, our method could be expanded to a number of situations and scaled up in combination with satellite remote sensing imagery or citizen science approaches. [ABSTRACT FROM AUTHOR]

Published

2017

12. Individual Tree Detection from Unmanned Aerial Vehicle (UAV) Derived Canopy Height Model in an Open Canopy Mixed Conifer Forest.

Author

Mohan, Midhun, Silva, Carlos Alberto, Klauberg, Carine, Jat, Prahlad, Catts, Glenn, Cardil, Adrián, Hudak, Andrew Thomas, and Dia, Mahendra

Subjects

DRONE aircraft, FOREST canopies, CONIFEROUS forests, ALGORITHMS, FORESTS & forestry

Abstract

Advances in Unmanned Aerial Vehicle (UAV) technology and data processing capabilities have made it feasible to obtain high-resolution imagery and three dimensional (3D) data which can be used for forest monitoring and assessing tree attributes. This study evaluates the applicability of low consumer grade cameras attached to UAVs and structure-from-motion (SfM) algorithm for automatic individual tree detection (ITD) using a local-maxima based algorithm on UAV-derived Canopy Height Models (CHMs). This study was conducted in a private forest at Cache Creek located east of Jackson city, Wyoming. Based on the UAV-imagery, we allocated 30 field plots of 20 m x 20 m. For each plot, the number of trees was counted manually using the UAV-derived orthomosaic for reference. A total of 367 reference trees were counted as part of this study and the algorithm detected 312 trees resulting in an accuracy higher than 85% (F-score of 0.86). Overall, the algorithm missed 55 trees (omission errors), and falsely detected 46 trees (commission errors) resulting in a total count of 358 trees. We further determined the impact of fixed tree window sizes (FWS) and fixed smoothing window sizes (SWS) on the ITD accuracy, and detected an inverse relationship between tree density and FWS. From our results, it can be concluded that ITD can be performed with an acceptable accuracy (F > 0.80) from UAV-derived CHMs in an open canopy forest, and has the potential to supplement future research directed towards estimation of above ground biomass and stem volume from UAV-imagery. [ABSTRACT FROM AUTHOR]

Published

2017

13. Predicting Stem Total and Assortment Volumes in an Industrial Pinus taeda L. Forest Plantation Using Airborne Laser Scanning Data and Random Forest.

Author

Alberto Silva, Carlos, Klauberg, Carine, Hudak, Andrew Thomas, Vierling, Lee Alexander, Wan Mohd Jaafar, Wan Shafrina, Mohan, Midhun, Garcia, Mariano, Ferraz, António, Cardil, Adrián, and Saatchi, Sassan

Subjects

LOBLOLLY pine, FOREST management, LIDAR, MACHINE learning, REMOTE sensing

Abstract

Improvements in the management of pine plantations result in multiple industrial and environmental benefits. Remote sensing techniques can dramatically increase the efficiency of plantation management by reducing or replacing time-consuming field sampling. We tested the utility and accuracy of combining field and airborne lidar data with Random Forest, a supervised machine learning algorithm, to estimate stem total and assortment (commercial and pulpwood) volumes in an industrial Pinus taeda L. forest plantation in southern Brazil. Random Forest was populated using field and lidar-derived forest metrics from 50 sample plots with trees ranging from three to nine years old. We found that a model defined as a function of only two metrics (height of the top of the canopy and the skewness of the vertical distribution of lidar points) has a very strong and unbiased predictive power. We found that predictions of total, commercial, and pulp volume, respectively, showed an adjusted R2 equal to 0.98, 0.98 and 0.96, with unbiased predictions of – 0.17%, – 0.12% and – 0.23%, and Root Mean Square Error (RMSE) values of 7.83%, 7.71% and 8.63%. Our methodology makes use of commercially available airborne lidar and widely used mathematical tools to provide solutions for increasing the industry efficiency in monitoring and managing wood volume. [ABSTRACT FROM AUTHOR]

Published

2017

14. Combined effect of pulse density and grid cell size on predicting and mapping aboveground carbon in fast-growing Eucalyptus forest plantation using airborne LiDAR data.

Author

Silva, Carlos, Hudak, Andrew, Klauberg, Carine, Vierling, Lee, Gonzalez-Benecke, Carlos, Padua Chaves Carvalho, Samuel, Rodriguez, Luiz, and Cardil, Adrián

Subjects

GRID cells, MATHEMATICAL mappings, EUCALYPTUS, REMOTE sensing, CARBON

Abstract

Background: LiDAR remote sensing is a rapidly evolving technology for quantifying a variety of forest attributes, including aboveground carbon (AGC). Pulse density influences the acquisition cost of LiDAR, and grid cell size influences AGC prediction using plot-based methods; however, little work has evaluated the effects of LiDAR pulse density and cell size for predicting and mapping AGC in fast-growing Eucalyptus forest plantations. The aim of this study was to evaluate the effect of LiDAR pulse density and grid cell size on AGC prediction accuracy at plot and stand-levels using airborne LiDAR and field data. We used the Random Forest (RF) machine learning algorithm to model AGC using LiDAR-derived metrics from LiDAR collections of 5 and 10 pulses m (RF5 and RF10) and grid cell sizes of 5, 10, 15 and 20 m. Results: The results show that LiDAR pulse density of 5 pulses m provides metrics with similar prediction accuracy for AGC as when using a dataset with 10 pulses m in these fast-growing plantations. Relative root mean square errors (RMSEs) for the RF5 and RF10 were 6.14 and 6.01%, respectively. Equivalence tests showed that the predicted AGC from the training and validation models were equivalent to the observed AGC measurements. The grid cell sizes for mapping ranging from 5 to 20 also did not significantly affect the prediction accuracy of AGC at stand level in this system. Conclusion: LiDAR measurements can be used to predict and map AGC across variable-age Eucalyptus plantations with adequate levels of precision and accuracy using 5 pulses m and a grid cell size of 5 m. The promising results for AGC modeling in this study will allow for greater confidence in comparing AGC estimates with varying LiDAR sampling densities for Eucalyptus plantations and assist in decision making towards more cost effective and efficient forest inventory. [ABSTRACT FROM AUTHOR]

Published

2017

15. Wildland fire typologies and extreme temperatures in NE Spain.

Author

Cardil, Adrián, Merenciano, David, and Molina-Terrén, Domingo Miguel

Subjects

WILDFIRES, FORESTS & forestry, TROPOSPHERE, EFFECT of drought on plants, CLIMATE change

Abstract

Understanding instrumental factors dealing with the development of large wildland fires is a need. Fire spread typologies and extreme temperature days were studied in the 1978-2012 period in Aragón (NE Spain). Temperature was examined at 850 hPa to characterize the low troposphere state and wildfires were grouped in three fire spread typologies: convective fires, wind-driven fires and topography-driven fires. The analysis of wildland fire propagation typologies revealed that convective fires burned the majority of total area burned, resulting in the larger and the most closely typology related to high temperature days (HTDs). Drought Code (DC) correlation with HTDs and wildland fire size was weak. [ABSTRACT FROM AUTHOR]

Published

2017

16. Remotely Sensed Tree Characterization in Urban Areas: A Review.

Author

Velasquez-Camacho, Luisa, Cardil, Adrián, Mohan, Midhun, Etxegarai, Maddi, Anzaldi, Gabriel, and de-Miguel, Sergio

Subjects

CITIES & towns, FORESTS & forestry, SCIENTIFIC knowledge, URBAN biodiversity, FOREST biodiversity, URBAN forestry, URBAN trees, URBAN plants

Abstract

Urban trees and forests provide multiple ecosystem services (ES), including temperature regulation, carbon sequestration, and biodiversity. Interest in ES has increased amongst policymakers, scientists, and citizens given the extent and growth of urbanized areas globally. However, the methods and techniques used to properly assess biodiversity and ES provided by vegetation in urban environments, at large scales, are insufficient. Individual tree identification and characterization are some of the most critical issues used to evaluate urban biodiversity and ES, given the complex spatial distribution of vegetation in urban areas and the scarcity or complete lack of systematized urban tree inventories at large scales, e.g., at the regional or national levels. This often limits our knowledge on their contributions toward shaping biodiversity and ES in urban areas worldwide. This paper provides an analysis of the state-of-the-art studies and was carried out based on a systematic review of 48 scientific papers published during the last five years (2016–2020), related to urban tree and greenery characterization, remote sensing techniques for tree identification, processing methods, and data analysis to classify and segment trees. In particular, we focused on urban tree and forest characterization using remotely sensed data and identified frontiers in scientific knowledge that may be expanded with new developments in the near future. We found advantages and limitations associated with both data sources and processing methods, from which we drew recommendations for further development of tree inventory and characterization in urban forestry science. Finally, a critical discussion on the current state of the methods, as well as on the challenges and directions for future research, is presented. [ABSTRACT FROM AUTHOR]

Published

2021

17. Regional Level Data Server for Fire Hazard Evaluation and Fuel Treatments Planning.

Author

Krsnik, Goran, Busquets Olivé, Eduard, Piqué Nicolau, Míriam, Larrañaga, Asier, Cardil, Adrián, García-Gonzalo, Jordi, and González Olabarría, José Ramón

Subjects

FIRE risk assessment, WILDFIRE prevention, FOREST fire prevention & control, FUEL, WILDFIRE risk, REMOTE sensing

Abstract

Both fire risk assessment and management of wildfire prevention strategies require different sources of data to represent the complex geospatial interaction that exists between environmental variables in the most accurate way possible. In this sense, geospatial analysis tools and remote sensing data offer new opportunities for estimating fire risk and optimizing wildfire prevention planning. Herein, we presented a conceptual design of a server that contained most variables required for predicting fire behavior at a regional level. For that purpose, an innovative and elaborated fuel modelling process and parameterization of all needed environmental and climatic variables were implemented in order to enable to more precisely define fuel characteristics and potential fire behaviors under different meteorological scenarios. The server, open to be used by scientists and technicians, is expected to be the steppingstone for an integrated tool to support decision-making regarding prevention and management of forest fires in Catalonia. [ABSTRACT FROM AUTHOR]

Published

2020

18. Carbon Emissions from Oil Palm Induced Forest and Peatland Conversion in Sabah and Sarawak, Malaysia.

Author

Wan Mohd Jaafar, Wan Shafrina, Said, Nor Fitrah Syazwani, Abdul Maulud, Khairul Nizam, Uning, Royston, Latif, Mohd Talib, Muhmad Kamarulzaman, Aisyah Marliza, Mohan, Midhun, Pradhan, Biswajeet, Saad, Siti Nor Maizah, Broadbent, Eben North, Cardil, Adrián, Silva, Carlos Alberto, and Takriff, Mohd Sobri

Subjects

OIL palm, CARBON emissions, FOREST conversion, ATMOSPHERIC carbon dioxide, INCENTIVE (Psychology), PALM oil industry, VEGETABLE oils

Abstract

The palm oil industry is one of the major producers of vegetable oil in the tropics. Palm oil is used extensively for the manufacture of a wide variety of products and its production is increasing by around 9% every year, prompted largely by the expanding biofuel markets. The rise in annual demand for biofuels and vegetable oil from importer countries has caused a dramatic increase in the conversion of forests and peatlands into oil palm plantations in Malaysia. This study assessed the area of forests and peatlands converted into oil palm plantations from 1990 to 2018 in the states of Sarawak and Sabah, Malaysia, and estimated the resulting carbon dioxide (CO2) emissions. To do so, we analyzed multitemporal 30-m resolution Landsat-5 and Landsat-8 images using a hybrid method that combined automatic image processing and manual analyses. We found that over the 28-year period, forest cover declined by 12.6% and 16.3%, and the peatland area declined by 20.5% and 19.1% in Sarawak and Sabah, respectively. In 2018, we found that these changes resulted in CO2 emissions of 0.01577 and 0.00086 Gt CO2-C yr−1, as compared to an annual forest CO2 uptake of 0.26464 and 0.15007 Gt CO2-C yr−1, in Sarawak and Sabah, respectively. Our assessment highlights that carbon impacts extend beyond lost standing stocks, and result in substantial direct emissions from the oil palm plantations themselves, with 2018 oil palm plantations in our study area emitting up to 4% of CO2 uptake by remaining forests. Limiting future climate change impacts requires enhanced economic incentives for land uses that neither convert standing forests nor result in substantial CO2 emissions. [ABSTRACT FROM AUTHOR]

Published

2020

19. Individual Tree Attribute Estimation and Uniformity Assessment in Fast-Growing Eucalyptus spp. Forest Plantations Using Lidar and Linear Mixed-Effects Models.

Author

Leite, Rodrigo Vieira, Silva, Carlos Alberto, Mohan, Midhun, Cardil, Adrián, Almeida, Danilo Roberti Alves de, Carvalho, Samuel de Pádua Chaves e, Jaafar, Wan Shafrina Wan Mohd, Guerra-Hernández, Juan, Weiskittel, Aaron, Hudak, Andrew T., Broadbent, Eben N., Prata, Gabriel, Valbuena, Ruben, Leite, Hélio Garcia, Taquetti, Mariana Futia, Soares, Alvaro Augusto Vieira, Scolforo, Henrique Ferraço, Amaral, Cibele Hummel do, Dalla Corte, Ana Paula, and Klauberg, Carine

Subjects

EUCALYPTUS, TREE farms, LIDAR, FOREST dynamics, UNIFORMITY, ALLOMETRIC equations

Abstract

Fast-growing Eucalyptus spp. forest plantations and their resultant wood products are economically important and may provide a low-cost means to sequester carbon for greenhouse gas reduction. The development of advanced and optimized frameworks for estimating forest plantation attributes from lidar remote sensing data combined with statistical modeling approaches is a step towards forest inventory operationalization and might improve industry efficiency in monitoring and managing forest resources. In this study, we first developed and tested a framework for modeling individual tree attributes in fast-growing Eucalyptus forest plantation using airborne lidar data and linear mixed-effect models (LME) and assessed the gain in accuracy compared to a conventional linear fixed-effects model (LFE). Second, we evaluated the potential of using the tree-level estimates for determining tree attribute uniformity across different stand ages. In the field, tree measurements, such as tree geolocation, species, genotype, age, height (Ht), and diameter at breast height (dbh) were collected through conventional forest inventory practices, and tree-level aboveground carbon (AGC) was estimated using allometric equations. Individual trees were detected and delineated from lidar-derived canopy height models (CHM), and crown-level metrics (e.g., crown volume and crown projected area) were computed from the lidar 3-D point cloud. Field and lidar-derived crown metrics were combined for ht, dbh, and AGC modeling using an LME. We fitted a varying intercept and slope model, setting species, genotype, and stand (alone and nested) as random effects. For comparison, we also modeled the same attributes using a conventional LFE model. The tree attribute estimates derived from the best LME model were used for assessing forest uniformity at the tree level using the Lorenz curves and Gini coefficient (GC). We successfully detected 96.6% of the trees from the lidar-derived CHM. The best LME model for estimating the tree attributes was composed of the stand as a random effect variable, and canopy height, crown volume, and crown projected area as fixed effects. The %RMSE values for tree-level height, dbh, and AGC were 8.9%, 12.1%, and 23.7% for the LFE model and improved to 7.3%, 7.1%, and 13.6%, respectively, for the LME model. Tree attributes uniformity was assessed with the Lorenz curves and tree-level estimations, especially for the older stands. All stands showed a high level of tree uniformity with GC values approximately 0.2. This study demonstrates that accurate detection of individual trees and their associated crown metrics can be used to estimate Ht, dbh, and AGC stocks as well as forest uniformity in fast-growing Eucalyptus plantations forests using lidar data as inputs to LME models. This further underscores the high potential of our proposed approach to monitor standing stock and growth in Eucalyptus—and similar forest plantations for carbon dynamics and forest product planning. [ABSTRACT FROM AUTHOR]

Published

2020

20. A Live Fuel Moisture Content Product from Landsat TM Satellite Time Series for Implementation in Fire Behavior Models.

Author

García, Mariano, Riaño, David, Yebra, Marta, Salas, Javier, Cardil, Adrián, Monedero, Santiago, Ramirez, Joaquín, Martín, M. Pilar, Vilar, Lara, Gajardo, John, and Ustin, Susan

Subjects

FIRE, LANDSAT satellites, TIME series analysis, HUMAN behavior models, STANDARD deviations, SALVAGE logging, MOISTURE

Abstract

Live Fuel Moisture Content (LFMC) contributes to fire danger and behavior, as it affects fire ignition and propagation. This paper presents a two layered Landsat LFMC product based on topographically corrected relative Spectral Indices (SI) over a 2000–2011 time series, which can be integrated into fire behavior simulation models. Nine chaparral sampling sites across three Landsat-5 Thematic Mapper (TM) scenes were used to validate the product over the Western USA. The relations between field-measured LFMC and Landsat-derived SIs were strong for each individual site but worsened when pooled together. The Enhanced Vegetation Index (EVI) presented the strongest correlations (r) and the least Root Mean Square Error (RMSE), followed by the Normalized Difference Infrared Index (NDII), Normalized Difference Vegetation Index (NDVI) and Visible Atmospherically Resistant Index (VARI). The relations between LFMC and the SIs for all sites improved after using their relative values and relative LFMC, increasing r from 0.44 up to 0.69 for relative EVI (relEVI), the best predictive variable. This relEVI served to estimate the herbaceous and woody LFMC based on minimum and maximum seasonal LFMC values. The understory herbaceous LFMC on the woody pixels was extrapolated from the surrounding pixels where the herbaceous vegetation is the top layer. Running simulations on the Wildfire Analyst (WFA) fire behavior model demonstrated that this LFMC product alone impacts significantly the fire spatial distribution in terms of burned probability, with average burned area differences over 21% after 8 h burning since ignition, compared to commonly carried out simulations based on constant values for each fuel model. The method could be applied to Landsat-7 and -8 and Sentinel-2A and -2B after proper sensor inter-calibration and topographic correction. [ABSTRACT FROM AUTHOR]

Published

2020

21. Comparison of Statistical Modelling Approaches for Estimating Tropical Forest Aboveground Biomass Stock and Reporting Their Changes in Low-Intensity Logging Areas Using Multi-Temporal LiDAR Data.

Author

Rex, Franciel Eduardo, Silva, Carlos Alberto, Dalla Corte, Ana Paula, Klauberg, Carine, Mohan, Midhun, Cardil, Adrián, Silva, Vanessa Sousa da, Almeida, Danilo Roberti Alves de, Garcia, Mariano, Broadbent, Eben North, Valbuena, Ruben, Stoddart, Jaz, Merrick, Trina, and Hudak, Andrew Thomas

Subjects

FOREST biomass, TROPICAL forests, DATA logging, STATISTICAL models, LOGGING, STANDARD deviations, LIDAR

Abstract

Accurately quantifying forest aboveground biomass (AGB) is one of the most significant challenges in remote sensing, and is critical for understanding global carbon sequestration. Here, we evaluate the effectiveness of airborne LiDAR (Light Detection and Ranging) for monitoring AGB stocks and change (ΔAGB) in a selectively logged tropical forest in eastern Amazonia. Specifically, we compare results from a suite of different modelling methods with extensive field data. The calibration AGB values were derived from 85 square field plots sized 50 × 50 m field plots established in 2014 and which were estimated using airborne LiDAR data acquired in 2012, 2014, and 2017. LiDAR-derived metrics were selected based upon Principal Component Analysis (PCA) and used to estimate AGB stock and change. The statistical approaches were: ordinary least squares regression (OLS), and nine machine learning approaches: random forest (RF), several variations of k-nearest neighbour (k-NN), support vector machine (SVM), and artificial neural networks (ANN). Leave-one-out cross-validation (LOOCV) was used to compare performance based upon root mean square error (RMSE) and mean difference (MD). The results show that OLS had the best performance with an RMSE of 46.94 Mg/ha (19.7%) and R² = 0.70. RF, SVM, and ANN were adequate, and all approaches showed RMSE ≤54.48 Mg/ha (22.89%). Models derived from k-NN variations all showed RMSE ≥64.61 Mg/ha (27.09%). The OLS model was thus selected to map AGB across the time-series. The mean (±sd—standard deviation) predicted AGB stock at the landscape level was 229.10 (±232.13) Mg/ha in 2012, 258.18 (±106.53) in 2014, and 240.34 (sd ± 177.00) Mg/ha in 2017, showing the effect of forest growth in the first period and logging in the second period. In most cases, unlogged areas showed higher AGB stocks than logged areas. Our methods showed an increase in AGB in unlogged areas and detected small changes from reduced-impact logging (RIL) activities occurring after 2012. We also detected that the AGB increase in areas logged before 2012 was higher than in unlogged areas. Based on our findings, we expect our study could serve as a basis for programs such as REDD+ and assist in detecting and understanding AGB changes caused by selective logging activities in tropical forests. [ABSTRACT FROM AUTHOR]

Published

2020

22. Combined Impact of Sample Size and Modeling Approaches for Predicting Stem Volume in Eucalyptus spp. Forest Plantations Using Field and LiDAR Data.

Author

Silva, Vanessa Sousa da, Silva, Carlos Alberto, Mohan, Midhun, Cardil, Adrián, Rex, Franciel Eduardo, Loureiro, Gabrielle Hambrecht, Almeida, Danilo Roberti Alves de, Broadbent, Eben North, Gorgens, Eric Bastos, Dalla Corte, Ana Paula, Silva, Emanuel Araújo, Valbuena, Rubén, and Klauberg, Carine

Subjects

TREE farms, LIDAR, FOREST monitoring, STANDARD deviations, FOREST surveys, DEAD trees, FOREST mapping

Abstract

Light Detection and Ranging (LiDAR) remote sensing has been established as one of the most promising tools for large-scale forest monitoring and mapping. Continuous advances in computational techniques, such as machine learning algorithms, have been increasingly improving our capability to model forest attributes accurately and at high spatial and temporal resolution. While there have been previous studies exploring the use of LiDAR and machine learning algorithms for forest inventory modeling, as yet, no studies have demonstrated the combined impact of sample size and different modeling techniques for predicting and mapping stem total volume in industrial Eucalyptus spp. tree plantations. This study aimed to compare the combined effects of parametric and nonparametric modeling methods for estimating volume in Eucalyptus spp. tree plantation using airborne LiDAR data while varying the reference data (sample size). The modeling techniques were compared in terms of root mean square error (RMSE), bias, and R2 with 500 simulations. The best performance was verified for the ordinary least-squares (OLS) method, which was able to provide comparable results to the traditional forest inventory approaches using only 40% (n = 63; ~0.04 plots/ha) of the total field plots, followed by the random forest (RF) algorithm with identical sample size values. This study provides solutions for increasing the industry efficiency in monitoring and managing forest plantation stem volume for the paper and pulp supply chain. [ABSTRACT FROM AUTHOR]

Published

2020

23. Measuring Individual Tree Diameter and Height Using GatorEye High-Density UAV-Lidar in an Integrated Crop-Livestock-Forest System.

Author

Dalla Corte, Ana Paula, Rex, Franciel Eduardo, Almeida, Danilo Roberti Alves de, Sanquetta, Carlos Roberto, Silva, Carlos A., Moura, Marks M., Wilkinson, Ben, Zambrano, Angelica Maria Almeyda, Cunha Neto, Ernandes M. da, Veras, Hudson F. P., Moraes, Anibal de, Klauberg, Carine, Mohan, Midhun, Cardil, Adrián, and Broadbent, Eben North

Subjects

EUCALYPTUS, TREE height, STANDARD deviations, FOREST management, FOREST surveys, TREE farms

Abstract

Accurate forest parameters are essential for forest inventory. Traditionally, parameters such as diameter at breast height (DBH) and total height are measured in the field by level gauges and hypsometers. However, field inventories are usually based on sample plots, which, despite providing valuable and necessary information, are laborious, expensive, and spatially limited. Most of the work developed for remote measurement of DBH has used terrestrial laser scanning (TLS), which has high density point clouds, being an advantage for the accurate forest inventory. However, TLS still has a spatial limitation to application because it needs to be manually carried to reach the area of interest, requires sometimes challenging field access, and often requires a field team. UAV-borne (unmanned aerial vehicle) lidar has great potential to measure DBH as it provides much higher density point cloud data as compared to aircraft-borne systems. Here, we explore the potential of a UAV-lidar system (GatorEye) to measure individual-tree DBH and total height using an automatic approach in an integrated crop-livestock-forest system with seminal forest plantations of Eucalyptus benthamii. A total of 63 trees were georeferenced and had their DBH and total height measured in the field. In the high-density (>1400 points per meter squared) UAV-lidar point cloud, we applied algorithms (usually used for TLS) for individual tree detection and direct measurement of tree height and DBH. The correlation coefficients (r) between the field-observed and UAV lidar-derived measurements were 0.77 and 0.91 for DBH and total tree height, respectively. The corresponding root mean square errors (RMSE) were 11.3% and 7.9%, respectively. UAV-lidar systems have the potential for measuring relatively broad-scale (thousands of hectares) forest plantations, reducing field effort, and providing an important tool to aid decision making for efficient forest management. We recommend that this potential be explored in other tree plantations and forest environments. [ABSTRACT FROM AUTHOR]

Published

2020

24. Erratum to: Combined effect of pulse density and grid cell size on predicting and mapping aboveground carbon in fast-growing Eucalyptus forest plantation using airborne LiDAR data.

Author

Silva, Carlos, Hudak, Andrew, Klauberg, Carine, Vierling, Lee, Gonzalez-Benecke, Carlos, Padua Chaves Carvalho, Samuel, Rodriguez, Luiz, and Cardil, Adrián

Subjects

CARBON, EUCALYPTUS, LIDAR

Published

2017

25. Improving Individual Tree Crown Delineation and Attributes Estimation of Tropical Forests Using Airborne LiDAR Data.

Author

Woodhouse, Iain Hector, Wan Mohd Jaafar, Wan Shafrina, Mohan, Midhun, Abdul Maulud, Khairul Nizam, Silva, Carlos Alberto, Omar, Hamdan, Hudak, Andrew Thomas, Klauberg, Carine, and Cardil, Adrián

Subjects

TROPICAL forests, PLANTS, FOREST management, BIOMASS, ALGORITHMS

Abstract

Individual tree crown (ITC) segmentation is an approach to isolate individual tree from the background vegetation and delineate precisely the crown boundaries for forest management and inventory purposes. ITC detection and delineation have been commonly generated from canopy height model (CHM) derived from light detection and ranging (LiDAR) data. Existing ITC segmentation methods, however, are limited in their efficiency for characterizing closed canopies, especially in tropical forests, due to the overlapping structure and irregular shape of tree crowns. Furthermore, the potential of 3-dimensional (3D) LiDAR data is not fully realized by existing CHM-based methods. Thus, the aim of this study was to develop an efficient framework for ITC segmentation in tropical forests using LiDAR-derived CHM and 3D point cloud data in order to accurately estimate tree attributes such as the tree height, mean crown width and aboveground biomass (AGB). The proposed framework entails five major steps: (1) automatically identifying dominant tree crowns by implementing semi-variogram statistics and morphological analysis; (2) generating initial tree segments using a watershed algorithm based on mathematical morphology; (3) identifying "problematic" segments based on predetermined set of rules; (4) tuning the problematic segments using a modified distance-based algorithm (DBA); and (5) segmenting and counting the number of individual trees based on the 3D LiDAR point clouds within each of the identified segment. This approach was developed in a way such that the 3D LiDAR points were only examined on problematic segments identified for further evaluations. 209 reference trees with diameter at breast height (DBH) ≥ 10 cm were selected in the field in two study areas in order to validate ITC detection and delineation results of the proposed framework. We computed tree crown metrics (e.g., maximum crown height and mean crown width) to estimate aboveground biomass (AGB) at tree level using previously published allometric equations. Accuracy assessment was performed to calculate percentage of correctly detected trees, omission and commission errors. Our method correctly identified individual tree crowns with detection accuracy exceeding 80 percent at both forest sites. Also, our results showed high agreement (R2 > 0.64) in terms of AGB estimates using 3D LiDAR metrics and variables measured in the field, for both sites. The findings from our study demonstrate the efficacy of the proposed framework in delineating tree crowns, even in high canopy density areas such as tropical rainforests, where, usually the traditional algorithms are limited in their performances. Moreover, the high tree delineation accuracy in the two study areas emphasizes the potential robustness and transferability of our approach to other densely forested areas across the globe. [ABSTRACT FROM AUTHOR]

Published

2018