MCC: Airborne LiDAR filtering method based on Multiscale Curvature...
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MCC R Documentation
Airborne LiDAR filtering method based on Multiscale Curvature Classification
Description
Airborne LiDAR filtering method of ground points based on Multiscale Curvature
Classification (Evans and Hudak, 2017; see references). This function is an R
wrapper around the library written by the original authors of the algorithm.
Usage
MCC(cloud, s = 1.5, t = 0.3)
Arguments
cloud
data.frame with 3 columns containing the coordinates of the point cloud.
s
numeric. Scale parameter. The optimal scale parameter is a function of the scale
of the objects (e.g., trees) on the ground, and the sampling interval (post spacing) of
the lidar data.
t
numeric. Curvature threshold
Details
There are two parameters that the user must define
to run MCC, the scale (s) parameter and the curvature threshold (t). The optimal
scale parameter is a function of 1) the scale of the objects (e.g., trees) on
the ground, and 2) the sampling interval (post spacing) of the lidar data.
Current lidar sensors are capable of collecting high density data (e.g., 8 pulses/m2)
that translate to a spatial sampling frequency (post spacing) of 0.35 m/pulse
(1/sqrt(8 pulses/m2) = 0.35 m/pulse), which is small relative to the size of
mature trees and will oversample larger trees (i.e., nominally multiple returns/tree).
Sparser lidar data (e.g., 0.25 pulses/m2) translate to a post spacing of 2.0 m/pulse
(1/sqrt(0.25 pulses/m2) = 2.0 m/pulse), which would undersample trees and fail
to sample some smaller trees (i.e., nominally <1 return/tree).
Therefore, a bit of trial and error is warranted to determine the best scale
and curvature parameters to use. Select a las tile containing a good variety
of canopy and terrain conditions, as it's likely the parameters that work best
there will be applicable to the rest of your project area tiles. As a starting
point: if the scale (post spacing) of the lidar survey is 1.5 m, then try 1.5.
Try varying it up or down by 0.5 m increments to see if it produces a more desirable
digital terrain model (DTM) interpolated from the classified ground returns in
the output file. Use units that match the units of the lidar data. For example,
if your lidar data were delivered in units of feet with a post spacing of 3 ft,
set the scale parameter to 3, then try varying it up or down by 1 ft increments
and compare the resulting interpolated DTMs. If the trees are large, then
it's likely that a scale parameter of 1 m (3 ft) will produce a cleaner DTM
than a scale parameter of 0.3 m (1 ft), even if the pulse density is 0.3 m
(1 ft). As for the curvature threshold, a good starting value to try might be
0.3 (if data are in meters; 1 if data are in feet), and then try varying this
up or down by 0.1 m increments (if data are in meters; 0.3 if data are in feet).
Value
An integer vector containing the ids of the points that belong on the ground.
References
Evans, Jeffrey S.; Hudak, Andrew T. 2007. A multiscale curvature
algorithm for classifying discrete return LiDAR in forested environments.
IEEE Transactions on Geoscience and Remote Sensing. 45(4): 1029-1038.
Examples
data(rmcc_cloud)
head(rmcc_cloud)
id_ground = MCC(rmcc_cloud, s = 3.5, t = 0.3)
RMCC documentation built on July 4, 2024, 9:06 a.m.
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| MCC | R Documentation |
Airborne LiDAR filtering method based on Multiscale Curvature Classification
Description
Airborne LiDAR filtering method of ground points based on Multiscale Curvature Classification (Evans and Hudak, 2017; see references). This function is an R wrapper around the library written by the original authors of the algorithm.
Usage
MCC(cloud, s = 1.5, t = 0.3)
Arguments
cloud |
data.frame with 3 columns containing the coordinates of the point cloud. |
s |
numeric. Scale parameter. The optimal scale parameter is a function of the scale of the objects (e.g., trees) on the ground, and the sampling interval (post spacing) of the lidar data. |
t |
numeric. Curvature threshold |
Details
There are two parameters that the user must define
to run MCC, the scale (s) parameter and the curvature threshold (t). The optimal
scale parameter is a function of 1) the scale of the objects (e.g., trees) on
the ground, and 2) the sampling interval (post spacing) of the lidar data.
Current lidar sensors are capable of collecting high density data (e.g., 8 pulses/m2)
that translate to a spatial sampling frequency (post spacing) of 0.35 m/pulse
(1/sqrt(8 pulses/m2) = 0.35 m/pulse), which is small relative to the size of
mature trees and will oversample larger trees (i.e., nominally multiple returns/tree).
Sparser lidar data (e.g., 0.25 pulses/m2) translate to a post spacing of 2.0 m/pulse
(1/sqrt(0.25 pulses/m2) = 2.0 m/pulse), which would undersample trees and fail
to sample some smaller trees (i.e., nominally <1 return/tree).
Therefore, a bit of trial and error is warranted to determine the best scale
and curvature parameters to use. Select a las tile containing a good variety
of canopy and terrain conditions, as it's likely the parameters that work best
there will be applicable to the rest of your project area tiles. As a starting
point: if the scale (post spacing) of the lidar survey is 1.5 m, then try 1.5.
Try varying it up or down by 0.5 m increments to see if it produces a more desirable
digital terrain model (DTM) interpolated from the classified ground returns in
the output file. Use units that match the units of the lidar data. For example,
if your lidar data were delivered in units of feet with a post spacing of 3 ft,
set the scale parameter to 3, then try varying it up or down by 1 ft increments
and compare the resulting interpolated DTMs. If the trees are large, then
it's likely that a scale parameter of 1 m (3 ft) will produce a cleaner DTM
than a scale parameter of 0.3 m (1 ft), even if the pulse density is 0.3 m
(1 ft). As for the curvature threshold, a good starting value to try might be
0.3 (if data are in meters; 1 if data are in feet), and then try varying this
up or down by 0.1 m increments (if data are in meters; 0.3 if data are in feet).
Value
An integer vector containing the ids of the points that belong on the ground.
References
Evans, Jeffrey S.; Hudak, Andrew T. 2007. A multiscale curvature algorithm for classifying discrete return LiDAR in forested environments. IEEE Transactions on Geoscience and Remote Sensing. 45(4): 1029-1038.
Examples
data(rmcc_cloud)
head(rmcc_cloud)
id_ground = MCC(rmcc_cloud, s = 3.5, t = 0.3)
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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