Reducing Uncertainty in Mapping of Mangrove Aboveground Biomass Using Airborne Discrete Return Lidar Data

Pereira, Francisca Rocha de Souza; Kampel, Milton; Soares, Mário Luiz Gomes; Estrada, Gustavo Calderucio Duque; Bentz, Cristina Maria; Vincent, Grégoire

doi:10.3390/rs10040637

Cited by 21 publications

(14 citation statements)

References 66 publications

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“…In fact, the finding of correlation analysis that variables significantly correlated with vegetation biomass varies largely with vegetation type implies that type-specific biomass estimations models should be constructed. Similarly, non-species-specific allometric growth models yielded larger errors than species-specific ones [69]. Urban vegetation cannot be regarded as a single vegetation type as it varies largely in biophysical characteristics and thus biomass.…”

Section: Discussionmentioning

confidence: 97%

Estimating Urban Vegetation Biomass from Sentinel-2A Image Data

Zhou

Chen

et al. 2020

Forests

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Urban vegetation biomass is a key indicator of the carbon storage and sequestration capacity and ecological effect of an urban ecosystem. Rapid and effective monitoring and measurement of urban vegetation biomass provide not only an understanding of urban carbon circulation and energy flow but also a basis for assessing the ecological function of urban forest and ecology. In this study, field observations and Sentinel-2A image data were used to construct models for estimating urban vegetation biomass in the case study of the east Chinese city of Xuzhou. Results show that (1) Sentinel-2A data can be used for urban vegetation biomass estimation; (2) compared with the Boruta based multiple linear regression models, the stepwise regression models—also multiple linear regression models—achieve better estimations (RMSE = 7.99 t/hm2 for low vegetation, 45.66 t/hm2 for broadleaved forest, and 6.89 t/hm2 for coniferous forest); (3) the models for specific vegetation types are superior to the models for all-type vegetation; and (4) vegetation biomass is generally lowest in September and highest in January and December. Our study demonstrates the potential of the free Sentinel-2A images for urban ecosystem studies and provides useful insights on urban vegetation biomass estimation with such satellite remote sensing data.

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Section: Discussionmentioning

confidence: 97%

Estimating Urban Vegetation Biomass from Sentinel-2A Image Data

Zhou

Chen

et al. 2020

Forests

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“…PLS is based on linear transitions from several original variables to relatively few orthogonal factors or latent variables. It is useful for establishing predictive models when the predictor variables are collinear [52]. As metrics extracted from GLAS may be collinear, a PLS model was developed.…”

Section: Biomass Modeling Methodsmentioning

confidence: 99%

Analyzing the Uncertainty of Estimating Forest Aboveground Biomass Using Optical Imagery and Spaceborne LiDAR

Sun

Wang

et al. 2019

Remote Sensing

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Accurate estimation of forest aboveground biomass (AGB) is important for carbon accounting. Forest AGB estimation has been conducted with a variety of data sources and prediction methods, but many uncertainties still exist. In this study, six prediction methods, including Gaussian processes, stepwise linear regression, nonlinear regression using a logistic model, partial least squares regression, random forest, and support vector machines were used to estimate forest AGB in Jiangxi Province, China, by combining Geoscience Laser Altimeter System (GLAS) data, Moderate Resolution Imaging Spectroradiometer (MODIS) data, and field measurements. We compared the effect of three factors (prediction methods, sample sizes of field measurements, and cross-validation settings) on the predictive quality of the methods. The results showed that the prediction methods had the most considerable effect on the prediction quality. In most cases, random forest produced more accurate estimates than the other methods. The sample sizes had an obvious effect on accuracy, especially for the random forest model. The accuracy increased with increasing sample sizes. The random forest algorithm with a large number of field measurements, was the most precise (coefficient of determination (R2) = 0.73, root mean square error (RMSE) = 23.58 Mg/ha). Increasing the number of folds within the cross-validation settings improved the R2 values. However, no apparent change occurred in RMSE for different numbers of folds. Finally, the wall-to-wall forest AGB map over the study area was generated using the random forest model.

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“…Los resultados de este estudio son consistentes con otros de estimación de biomasa aérea en bosques tropicales. Cada una de estas métricas (P80, P90 y P95) se combinan con otras métricas de densidad o estadísticas de la distribución de altura para conformar los modelos generados por Clark et al (2011) en Costa Rica, en manglares de Brasil (Rocha de Souza et al, 2018), así como en bosques templados (Lefsky et al, 2002). Los percentiles P80 y P90 (9.6 m -10.6 m) corresponden al patrón de altura promedio para este tipo de vegetación.…”

Section: Discussionunclassified

“…Por otro lado, en los dos tipos de selva estudiados, el percentil 95 y la altura media, además de dos métricas relacionadas a la cobertura del dosel (el porcentaje de los primeros retornos encima de 2 m y el porcentaje de los primeros retornos encima de la altura media) contribuyeron significativamente a predecir la biomasa mediante modelos de regresión lineal. La idea principal de usar dos métricas en cada modelo fue crear una relación simple que involucre la distribución de altura y la profundidad en que los retornos LiDAR penetran el arbolado, como lo señalan Rocha de Souza et al (2018), además, es importante señalar que la adición de más variables en los modelos no incrementó significativamente la variación explicada.…”

Section: Discussionunclassified

“…En este sentido, estudios de propósito similar (Deo et al, 2017;Rocha de Souza et al, 2018) registran errores de geoposicionamiento de los sitios de muestreo menores a 1 m. No obstante, White et al (2013) recomiendan errores de geoposicionamiento de hasta 5 m en los sitios de muestreo en campo, además de otros métodos para disminuir el error, como registrar con el global positioning system (GPS) un mínimo de 500 puntos por parcela; aplicar corrección diferencial o incrementar el tamaño de parcela para asegurar un traslape suficiente.…”

Section: Discussionunclassified

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Transectos de datos LiDAR: una estrategia de muestreo para estimar biomasa aérea en áreas forestales

Ortiz-Reyes

Valdez-Lazalde

Ángeles‐Pérez

et al. 2019

MYB

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La estimación y el mapeo de la biomasa aérea sobre áreas extensas puede realizarse haciendo uso de las herramientas que ofrece la percepción remota. El objetivo de este estudio fue estimar la biomasa aérea de dos tipos de selva mediana: subperennifolia (SMSP) y subcaducifolia (SMSC) en la península de Yucatán, México, empleando métricas generadas a partir de datos Light Detection and Ranging (LiDAR). Se usaron datos de 365 unidades de muestreo del Inventario Nacional Forestal y de Suelos (INFyS) de México para calibrar modelos de biomasa aérea usando regresión lineal múltiple y Random Forest (RF). Con estos modelos se mapeó la biomasa aérea sobre franjas de datos LiDAR. El modelo de regresión transformado logró explicar la varianza en un 62% (RMSE = 41.44 Mg ha-1 para SMSP y 36.60 Mg ha-1 para SMSC) para ambos tipos de vegetación. Los modelos generados a través de RF lograron explicar la varianza en un 57% (RMSE = 40.73 Mg ha-1) para la SMSP y solo de 52% (RMSE = 35.10 Mg Ha-1) para la SMSC. El desfase entre la toma de datos en campo y LiDAR, así como el error en la precisión de las coordenadas de los sitios de inventario, son factores reconocidos que influyeron en los resultados. A pesar de lo anterior, las estimaciones obtenidas podrían servir de base para estimar el inventario completo de biomasa en el área de estudio incorporando datos espectrales derivados de un sensor remoto que cubra la totalidad de esta.

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Reducing Uncertainty in Mapping of Mangrove Aboveground Biomass Using Airborne Discrete Return Lidar Data

Cited by 21 publications

References 66 publications

Estimating Urban Vegetation Biomass from Sentinel-2A Image Data

Estimating Urban Vegetation Biomass from Sentinel-2A Image Data

Analyzing the Uncertainty of Estimating Forest Aboveground Biomass Using Optical Imagery and Spaceborne LiDAR

Transectos de datos LiDAR: una estrategia de muestreo para estimar biomasa aérea en áreas forestales

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