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<!-- README.md is generated from README.Rmd. Please edit that file -->dfoliatR <img src="man/figures/logo.png" align="right" width="120" />
<!-- badges: start --> <!-- badges: end -->The goal of dfoliatR
is to provide dendrochronologists with tools for
identifying and analyzing the signatures of insect defoliators preserved
in tree rings. The methods it employs closely follow (or in some cases
exactly replicate) OUTBREAK, a FORTRAN program available from the
Dendrochronological Program
Library.
When using dfoliatR
in a publication, please cite the paper:
Guiterman, CH, AM Lynch, and JN Axelson (2020)
dfoliatR
: An R package for detection and analysis of insect defoliation signals in tree rings. Dendrochronologia. DOI: 10.1016/j.dendro.2020.125750.
Installation
You can install the released version of dfoliatR from CRAN with:
install.packages("dfoliatR")
And the development version from GitHub with:
# install.packages("devtools")
devtools::install_github("chguiterman/dfoliatR")
Usage
The package requires users to input two sets of tree-ring data:
standardized ring widths of individual host trees and a standardized
tree-ring chronology from a local non-host tree species or climate
series. dfoliatR
combines these to remove the climate signal
represented by the non-host chronology from the host tree series. What’s
left should represent a disturbance signal. Then dfoliatR
identifies
defoliation events in the host tree series.
We recommend that the input tree-ring data be standardized in either
ARSTAN or the dplR
R package. If there is more than one ring-width
series from the same tree, these should be standardized and averaged to
the tree level. In ARSTAN, make sure to output ‘.TRE’ files and read
them into R with the read.compact()
function in dplR
. If you choose
to standardize raw ring widths in dplR
with detrend()
, then use the
treeMean()
function to generate tree-level series. All data input to
dfoliatR
needs to be an rwl
object as defined in dplR
.
Example
Here we briefly explore defoliation and outbreaks patterns for a Douglas-fir site in New Mexico. These data are included in the package
library(dfoliatR)
## load the data
data("dmj_h")
data("dmj_nh")
To start out, we identify defoliation events on individual trees,
## Identify defoliation signals
dmj_defol <- defoliate_trees(host_tree = dmj_h, nonhost_chron = dmj_nh)
## Plot the results
plot_defol(dmj_defol)
<img src="man/figures/README-unnamed-chunk-3-1.png" width="100%" />
And then scale up to outbreaks by compositing across the site via
## Identify site-level outbreak patterns
dmj_obr <- outbreak(dmj_defol)
## Plot those results
plot_outbreak(dmj_obr)
<img src="man/figures/README-unnamed-chunk-4-1.png" width="100%" />
Further resources
Analyses of the tree series (termed defol
objects) can be done via:
plot_defol()
defol_stats()
get_defol_events()
sample_depth()
To identify ecologically-significant outbreak events, use the
outbreak()
function. Various filters are available to aid users in
defining outbreak thresholds. Analyses of outbreak series (termed obr
objects) can be done via:
plot_outbreak()
outbreak_stats()
For the full range of usage in dfoliatR
, please visit the
introduction
vignette.
Questions, concerns, problems, ideas, or want to contribute?
Please contact the author, Chris Guiterman