SDLfilter

Overview

SDLfilter contains a variety of functions to screen GPS/Argos locations and to assess the adequacy of sample size of tracking data for animal distribution analysis.

Installation

``````# The official version from CRAN:
install.packages("SDLfilter")

# Or the development version from GitHub:
install.packages("devtools")
``````

Usage

``````library(SDLfilter)
``````

1. Location filtering

There are three main filtering functions.

• dupfilter filters temporal and spatial duplicates.
• ddfilter filters locations with high error.
• depthfilter filters locations by water depth.

1-1. Load tracking data

``````data(turtle)
``````

1-2. Remove temporal and spatial duplicates

``````turtle.dup <- dupfilter(turtle)
``````

1-3. Remove biologically unrealistic fixes

``````## Calculate the maximum linear speed between two consecutive locations
V <- vmax(turtle.dup)

## Calculate the maximum one-way linear speed of a loop trip
VLP <- vmaxlp(turtle.dup)

## Run ddfilter
turtle.dd <- ddfilter(turtle.dup, vmax=V, vmaxlp=VLP)
``````

1-4. Plot data

Click to show code

`````` # Entire area
p1 <- map_track(turtle.dup, bgmap=Australia, point.size = 2, line.size = 0.5, axes.lab.size = 0,
sb.distance=200, multiplot = FALSE, point.bg = "red",
title.size=15, title="Entire area")[[1]] +
geom_point(aes(x=lon, y=lat), data=turtle.dd, size=2, fill="yellow", shape=21)+
geom_point(aes(x=x, y=y), data=data.frame(x=c(154, 154), y=c(-22, -22.5)),
size=3, fill=c("yellow", "red"), shape=21) +
annotate("text", x=c(154.3, 154.3), y=c(-22, -22.5), label=c("Retained", "Removed"),
colour="black", size=4, hjust = 0)

# Zoomed in
p2 <- map_track(turtle.dup, bgmap=SandyStrait, xlim=c(152.7, 153.2), ylim=(c(-25.75, -25.24)),
axes.lab.size = 0, sb.distance=10, point.size = 2, point.bg = "red", line.size = 0.5,
multiplot = FALSE, title.size=15, title="Zoomed in")[[1]] +
geom_path(aes(x=lon, y=lat), data=turtle.dd, size=0.5, colour="black", linetype=1) +
geom_point(aes(x=lon, y=lat), data=turtle.dd, size=2, colour="black", shape=21, fill="yellow")

## plot
gridExtra::grid.arrange(p1, p2, layout_matrix=cbind(1,2))
``````

2. Assessing sample sizes (probability-based approach)

2-1. Input UDs

The input data can be either a matrix or a list of RasterLayer objects. Each row of the matrix or each RasterLayer object contains the probability distribution of an animal. The function assumes that each column of a matrix is associated with a unique geographical location, therefore it is critical that the grid size and geographical extent are consistent across UDs. In this example, the grid size was 1km and the geographical extent was 1901789, 1972789, -2750915, -2653915 (EPSG:3577) across all 15 layers.

Click to show an example code of UD estimation.

``````library(adehabitatHR); library(raster)

## Tracking data
data(flatback)
flatback <- track_param(flatback, param = "time") # calculate time between successive locations
flatback_id <- unique(flatback\$id)

## Data range with 5km buffer
buff <- 5e+3
xmin <- min(flatback\$x) - buff; xmax <- max(flatback\$x) + buff
ymin <- min(flatback\$y) - buff; ymax <- max(flatback\$y) + buff

## Make a grid layer
cell.size <- 1e+3 # (1km x 1km)
x <- seq(xmin, xmax, cell.size)
y <- seq(ymin, ymax, cell.size)
xy.df <- expand.grid(x = x, y = y)
xy.coords <- SpatialPixels(SpatialPoints(xy.df))
xy.sp <- SpatialPoints(xy.coords, proj4string = CRS("+init=epsg:3577"))
z <- rep(1, nrow(xy.df))
xyz <- cbind(xy.df, z)
grid_spdf <- SpatialPixelsDataFrame(xy.coords, xyz)

## UD per turtle
ud_raster <- list()
for(i in 1:length(flatback_id)){

## ID
ID <- flatback_id[i]

## Tracking data
turtle.data <- with(flatback, flatback[id %in% ID, ])

## Creates an object of class Itraj
data.ltraj <- with(turtle.data, as.ltraj(turtle.data[,c("x", "y")], date=DateTime, id=ID, burst=ID))

## Parameters for BRB
TM = quantile(turtle.data\$pTime, probs = 0.95, na.rm = TRUE)*3600
LM = 50
dp = BRB.likD(data.ltraj, Tmax=TM, Lmin=LM)
HM = 100

## Estimate the UD
ud <- BRB(data.ltraj, D=dp, Tmax=TM, Lmin=LM, hmin=HM, grid=grid_spdf, type="UD")

## Convert the UD to raster
ud_raster[[i]] <- raster(ud)
}
``````

``````# A matrix
data(ud_matrix)

# Or a list of RasterLayer
data(ud_raster)
``````

2-2. Calculate overlap probability from 3000 random permutation (\~sample size x 200)

It will take some time to run this code depending on the number of iterations and the machine specs. The runtime was about 7 minutes for 3000 iterations on a linux machine (Intel i7-8850H CPU @ 2.60GHz, 32GB RAM).

``````overlap <- boot_overlap(ud_matrix, R = 3000, method = "PHR")
``````

2-3. Find the minimum sample size required to estimate the general distribution

As described in the main text, an asymptote was considered once the mean overlap probability exceeded 95% of the estimated horizontal asymptote. The sample size linked to this value was deemed to be the minimum sample size required to represent the general distribution of the group.

``````a <- asymptote(overlap, upper.degree = 10)
``````

2-4. Plot the mean probability and rational function fit relative to the sample sizes (n).

Click to show code

``````ggplot(data = overlap\$summary)+
geom_point(aes(x = N, y = mu), alpha = 0.5) +
geom_path(data = a\$results, aes(x = x, y = ys)) +
geom_vline(xintercept = a\$min.n, linetype = 2) +
scale_x_continuous(breaks = seq(0, 15, 3), limits = c(2,15), name = "Animals tracked (n)") +
scale_y_continuous(limits = c(0,1), name = "Overlap probability")
``````

Please see the package help pages and Shimada et al. (2012, 2016, 2021) for more details.

References

If you use the function ddfilter, please cite

Shimada T, Jones R, Limpus C, Hamann M (2012) Improving data retention and home range estimates by data-driven screening. Mar Ecol Prog Ser 457:171-180 doi: 10.3354/meps09747

If you use the functions dupfilter or depthfilter, please cite

Shimada T, Limpus C, Jones R, Hazel J, Groom R, Hamann M (2016) Sea turtles return home after intentional displacement from coastal foraging areas. Mar Biol 163:1-14 doi: 10.1007/s00227-015-2771-0

If you use the functions boot_overlap or boot_area, please cite

Shimada, T, Thums, M, Hamann, M, et al. (2021) Optimising sample sizes for animal distribution analysis using tracking data. Methods Ecol Evol 12(2):288-297 doi: 10.1111/2041-210X.13506

Current version

2.1.1 (04 July 2021)

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SDLfilter documentation built on July 20, 2021, 9:07 a.m.