Your search keyword '"sparse point clouds."' showing total 2 results

1. Options for estimating horizontal visibility in hemiboreal forests using sparse airborne laser scanning data and forest inventory data

Author

Lang Mait, Vennik Kersti, Põldma Andrus, and Nilson Tiit

Subjects

forest, horizontal visibility, airborne lidar, structural diversity, sparse point clouds., Forestry, SD1-669.5

Abstract

Horizontal visibility v in hemiboreal forest transects was measured in the field and then predicted, both from forest inventory (FI) data and from airborne laser scanning (ALS) data. Stand density N and mean diameter at breast height D were used as arguments in an FI predictive model assuming Poisson distribution of trees on a horizontal plane. It was found that a lack of FI data on forest regrowth and understorey trees caused v to be overestimated. Point cloud metrics of sparse ALS data from summer 2017 and spring 2019 were used as predictive variables for v in regression models. The best models were based on three variables: the 10th percentile of the point cloud height distribution, relative density of returns in a horizontal layer ranging 0.7–2.2 m above the ground, and canopy cover. The models had a coefficient of determination of up to 67% and a residual standard error of less than 25 m. In forests in which fertile soil produces rapid height growth of understorey woody vegetation after recent thinning, visibility was found to be substantially overestimated because the understorey was not detected by the lidar measurements.

Published

2021

2. Options for estimating horizontal visibility in hemiboreal forests using sparse airborne laser scanning data and forest inventory data.

Author

Lang, Mait, Vennik, Kersti, Põldma, Andrus, and Nilson, Tiit

Subjects

*AIRBORNE lasers, *FOREST surveys, *SPECIFIC gravity, *POISSON distribution, *POINT cloud, *UNDERSTORY plants

Abstract

Horizontal visibility v in hemiboreal forest transects was measured in the field and then predicted, both from forest inventory (FI) data and from airborne laser scanning (ALS) data. Stand density N and mean diameter at breast height D were used as arguments in an FI predictive model assuming Poisson distribution of trees on a horizontal plane. It was found that a lack of FI data on forest regrowth and understorey trees caused v to be overestimated. Point cloud metrics of sparse ALS data from summer 2017 and spring 2019 were used as predictive variables for v in regression models. The best models were based on three variables: the 10th percentile of the point cloud height distribution, relative density of returns in a horizontal layer ranging 0.7–2.2 m above the ground, and canopy cover. The models had a coefficient of determination of up to 67% and a residual standard error of less than 25 m. In forests in which fertile soil produces rapid height growth of understorey woody vegetation after recent thinning, visibility was found to be substantially overestimated because the understorey was not detected by the lidar measurements. [ABSTRACT FROM AUTHOR]

Published

2020