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R package for Airborne LiDAR Data Manipulation and Visualization for Forestry Applications
The lidR package provides functions to read and write
.las
and .laz
files, plot point clouds,
compute metrics using an area-based approach, compute digital canopy
models, thin LiDAR data, manage a collection of LAS/LAZ files,
automatically extract ground inventories, process a collection of tiles
using multicore processing, segment individual trees, classify points
from geographic data, and provides other tools to manipulate LiDAR data
in a research and development context.
:book: Read the book to get started with the lidR package. See changelogs on NEW.md
To cite the package use citation()
from within R:
citation("lidR")
#> Roussel, J.R., Auty, D., Coops, N. C., Tompalski, P., Goodbody, T. R. H., Sánchez Meador, A., Bourdon, J.F., De Boissieu, F., Achim, A. (2021). lidR : An R package for analysis of Airborne Laser Scanning (ALS) data. Remote Sensing of Environment, 251 (August), 112061. <doi:10.1016/j.rse.2020.112061>.
#> Jean-Romain Roussel and David Auty (2023). Airborne LiDAR Data Manipulation and Visualization for Forestry Applications. R package version 3.1.0. https://cran.r-project.org/package=lidR
In R-fashion style the function plot
, based on
rgl
, enables the user to display, rotate and zoom a point
cloud. Because rgl
has limited capabilities with respect to
large datasets, we also made a package lidRviewer with
better display capabilities.
<- readLAS("<file.las>")
las plot(las)
lidR
has several algorithms from the literature to
compute canopy height models either point-to-raster based or
triangulation based. This allows testing and comparison of some methods
that rely on a CHM, such as individual tree segmentation or the
computation of a canopy roughness index.
<- readLAS("<file.las>")
las
# Khosravipour et al. pitfree algorithm
<- c(0,2,5,10,15)
thr <- c(0, 1.5)
edg <- rasterize_canopy(las, 1, pitfree(thr, edg))
chm
plot(chm)
lidR
enables the user to manage, use and process a
collection of las
files. The function
readLAScatalog
builds a LAScatalog
object from
a folder. The function plot
displays this collection on an
interactive map using the mapview
package (if
installed).
<- readLAScatalog("<folder/>")
ctg plot(ctg, map = TRUE)
From a LAScatalog
object the user can (for example)
extract some regions of interest (ROI) with clip_roi()
.
Using a catalog for the extraction of the ROI guarantees fast and
memory-efficient clipping. LAScatalog
objects allow many
other manipulations that can be done with multicore processing.
The segment_trees()
function has several algorithms from
the literature for individual tree segmentation, based either on the
digital canopy model or on the point-cloud. Each algorithm has been
coded from the source article to be as close as possible to what was
written in the peer-reviewed papers. Our goal is to make published
algorithms usable, testable and comparable.
<- readLAS("<file.las>")
las
<- segment_trees(las, li2012())
las <- random.colors(200)
col plot(las, color = "treeID", colorPalette = col)
Most of the lidR functions can seamlessly process a set of tiles and
return a continuous output. Users can create their own methods using the
LAScatalog
processing engine via the
catalog_apply()
function. Among other features the engine
takes advantage of point indexation with lax files, takes care of
processing tiles with a buffer and allows for processing big files that
do not fit in memory.
# Load a LAScatalog instead of a LAS file
<- readLAScatalog("<path/to/folder/>")
ctg
# Process it like a LAS file
<- rasterize_canopy(ctg, 2, p2r())
chm <- random.colors(50)
col plot(chm, col = col)
lidR can read full waveform data from LAS files and provides interpreter functions to convert the raw data into something easier to manage and display in R. The support of FWF is still in the early stages of development.
<- readLAS("<fullwaveform.las>")
fwf
# Interpret the waveform into something easier to manage
<- interpret_waveform(fwf)
las
# Display discrete points and waveforms
<- plot(fwf, colorPalette = "red", bg = "white")
x plot(las, color = "Amplitude", add = x)
lidR is developed openly at Laval University.
lidR
package between 2015 and 2018
was made possible thanks to the financial support of the AWARE project (NSERC CRDPJ
462973-14); grantee Prof
Nicholas Coops.lidR
package between 2018 and 2021
was made possible thanks to the financial support of the Ministère
des Ressources naturelles et des Forêts.lidR
dependencies on GNU/Linux# Ubuntu
sudo add-apt-repository ppa:ubuntugis/ubuntugis-unstable
sudo apt-get update
sudo apt-get install libgdal-dev libgeos++-dev libudunits2-dev libproj-dev libx11-dev libgl1-mesa-dev libglu1-mesa-dev libfreetype6-dev libxt-dev libfftw3-dev
# Fedora
sudo dnf install gdal-devel geos-devel udunits2-devel proj-devel mesa-libGL-devel mesa-libGLU-devel freetype-devel libjpeg-turbo-devel
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.
Health stats visible at Monitor.