Assessment of Carbon Stock at Tree Level Using Terrestrial Laser Scanning Vs. Traditional Methods in Tropical Forest, India

Singhal, Jayant; Srivastava, Gaurav; Reddy, C. Sudhakar; Rajashekar, G.; Jha, C. S.; Rao, P. V. Krishna; Reddy, G. V. Prabhakara; Roy, P. S.

doi:10.1109/jstars.2021.3076195

Cited by 7 publications

(9 citation statements)

References 12 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Moreover, LiDAR data from terrestrial and spaceborne platforms have proven highly effective in accurately estimating AGB across various forest types in India (Dhanda et al, 2017;Mohite et al, 2024;Singh et al, 2023;Singhal et al, 2021). Integration of multi-sensor data, including passive optical, SAR, and LiDAR data, has demonstrated superior AGB estimation compared to single sensor data (Fararoda et al, 2021;Malhi et al, 2022;.…”

Section: Rs-forest Biomass: Indian Scenariomentioning

confidence: 99%

Forest Biomass Assessment Using Multisource Earth Observation Data: Techniques, Data Sets and Applications

Dadhwal,

Nandy

2024

J Indian Soc Remote Sens

View full text Add to dashboard Cite

Section: Rs-forest Biomass: Indian Scenariomentioning

confidence: 99%

Forest Biomass Assessment Using Multisource Earth Observation Data: Techniques, Data Sets and Applications

Dadhwal,

Nandy

2024

J Indian Soc Remote Sens

View full text Add to dashboard Cite

“…TLS enhances the conventional method that empirically estimates biomass from structural properties of vegetation (e.g., canopy size, density, species composition). Plant structure derived from laser scanning products (i.e., canopy height, understory cover, and foliage diversity) correlates strongly with biomass measurements, and thus suggests great potential in biomass change mapping (Hall et al., 2011) and carbon budget estimation (Harman et al., 2014; Singhal et al., 2021; Stovall et al., 2018). Very specific vertical profiling from TLS can predict species richness and ultimately inform change in biodiversity (Anderson et al., 2021).…”

Section: Sensors and Platforms For Observing Cz Disturbancementioning

confidence: 99%

Seeing the Disturbed Forest for the Trees: Remote Sensing Is Underutilized to Quantify Critical Zone Response to Unprecedented Disturbance

et al. 2023

View full text Add to dashboard Cite

Understanding the severity and extent of near surface critical zone (CZ) disturbances and their ecosystem response is a pressing concern in the face of increasing human and natural disturbances. Predicting disturbance severity and recovery in a changing climate requires comprehensive understanding of ecosystem feedbacks among vegetation and the surrounding environment, including climate, hydrology, geomorphology, and biogeochemistry. Field surveys and satellite remote sensing have limited ability to effectively capture the spatial and temporal variability of disturbance and CZ properties. Technological advances in remote sensing using new sensors and new platforms have improved observations of changes in vegetation canopy structure and productivity; however, integrating measures of forest disturbance from various sensing platforms is complex. By connecting the potential for remote sensing technologies to observe different CZ disturbance vectors, we show that lower severity disturbance and slower vegetation recovery are more difficult to quantify. Case studies in montane forests from the western United States highlight new opportunities, including evaluating post‐disturbance forest recovery at multiple scales, shedding light on understory vegetation regrowth, detecting specific physiological responses, and refining ecohydrological modeling. Learning from regional CZ disturbance case studies, we propose future directions to synthesize fragmented findings with (a) new data analysis using new or existing sensors, (b) data fusion across multiple sensors and platforms, (c) increasing the value of ground‐based observations, (d) disturbance modeling, and (e) synthesis to improve understanding of disturbance.

show abstract

“…We are now able to observe forests not just in terms of their re ectance spectrum but also in terms of their texture (Ferreira et al, 2019), phenology (Araya et al, 2018;Srinet et al, 2020) and structure (Neuenschwander & Pitts, 2019;Potapov et al, 2021;Singhal et al, 2021) and from varied platforms starting from Satellite based to Airborne (UAVs and Airplanes) to Terrestrial Sensors.…”

Section: Introductionmentioning

confidence: 99%

Characterization of tropical forests at community level: combining spectral, phenological, structural datasets using random forest algorithm

Singhal,

Rajwadi,

Malek

et al. 2024

Biodivers Conserv

Self Cite

View full text Add to dashboard Cite

Since the inception of satellite remote sensing as a technology, characterization of forests has been one of the major application of it. Characterization of forests at Species level is essential for sustainable management of biodiversity. Recent advancements in remote sensing as a technology has enable us to observe not only the re ectance spectra of forests from space, but also their phenology and structure. In this study Earth Observation (EO) datasets were divided into 3 parts namely spectral data, structural and phenological data. Random forest algorithm was applied on the 3 sets of EO data and eld inventorybased tree community classes to generate tree community maps of Purna wildlife sanctuary. Classi cation accuracy achieved from spectral datasets (79.08% to 87.23%) was more than phenological dataset (80.94%) which was more than structural datasets (74.11% to 81.49%). A model with combination of predictors from the 3 datasets increased the classi cation accuracy to 90.29%. Some salient ndings of this study are 1) in general with the current sensors the accuracies achieved for tree community mapping is Spectral datasets> Phenological datasets> Structural datasets 2) Signi cant increase in accuracy can be achieved by combining the three datasets 3) In case of spectral datasets, the last image before the start of monsoon season gave the best accuracy 4) In the case of spectral datasets, relatively modern spectral bands contributed signi cantly more to the model as compared to trivial bands.

show abstract

Assessment of Carbon Stock at Tree Level Using Terrestrial Laser Scanning Vs. Traditional Methods in Tropical Forest, India

Cited by 7 publications

References 12 publications

Forest Biomass Assessment Using Multisource Earth Observation Data: Techniques, Data Sets and Applications

Forest Biomass Assessment Using Multisource Earth Observation Data: Techniques, Data Sets and Applications

Seeing the Disturbed Forest for the Trees: Remote Sensing Is Underutilized to Quantify Critical Zone Response to Unprecedented Disturbance

Characterization of tropical forests at community level: combining spectral, phenological, structural datasets using random forest algorithm

Contact Info

Product

Resources

About