Background
Population parameters such as reproductive success are critical for sustainably managing ungulate populations, however obtaining these data is often difficult, expensive, and invasive. Movement-based methods that leverage Global Positioning System (GPS) relocation data to identify parturition offer an alternative to more invasive techniques such as vaginal implant transmitters, but thus far have only been applied to relocation data with a relatively fine (one fix every  \u3c 8 h) temporal resolution. We employed a machine learning method to classify parturition/calf survival in cow elk in southeastern Kentucky, USA, using 13-h GPS relocation data and three simple movement metrics, training a random forest on cows that successfully reared their calf to a week old.
Results
We developed a decision rule based upon a predicted probability threshold across individual cow time series, accurately classifying 89.5% (51/57) of cows with a known reproductive status. When used to infer status of cows whose reproductive outcome was unknown, we classified 48.6% (21/38) as successful, compared to 85.1% (40/47) of known-status cows.
Conclusions
While our approach was limited primarily by fix acquisition success, we demonstrated that coarse collar fix rates did not limit inference if appropriate movement metrics are chosen. Movement-based methods for determining parturition in ungulates may allow wildlife managers to extract more vital rate information from GPS collars even if technology and related data quality are constrained by cost

Cox, John J.

Crank, R. Daniel

Hast, John T.

Hooven, Nathan D.

Jenkins, Gabe

McDermott, Joseph R.

Springer, Matthew T.

Williams, Kathleen E.

English

University of Kentucky

‘User-friendly’ R workflow for using low-fix rateGPS telemetry to determine ungulate reproductivesuccessAccompanying code to ‘Using low-fix rate GPS telemetry to expandestimates of ungulate reproductive success’Nathan D. Hooven28 Oct 2021User-friendly R workflow for using low-fix rate GPS telemetry to determine ungulate re-productive successThe goal of this summary and accompanying code is to illustrate the relative ease of dataprocessing for inference of ungulate parturition success and outline the general processneeded to train a random forest (RF) to classify parturition and non-parturition focal daysacross a time series of GPS relocation data. This approach is flexible to coarse collarsampling schemes and can incorporate a wide variety of spatial variables, including met-rics of movement and habitat use. Our goal was to present straightforward code that isuseful to biologists and managers with only a fundamental understanding of R program-ming and geospatial processing, but who may be interested in examining historical and/orcontemporary GPS data for potential signals of reproductive success.The complete R script and dataset used in this workflow are available on GitHub: https://github.com/nhooven/elk-repro-success-user-friendlyRequired packages (and versions used to write script)• ‘tidyverse’ (1.3.0; incl. ‘ggplot2’, ‘dplyr’, ‘tidyr’, ‘readr’, ‘purrr’, ‘tibble’, ‘stringr’, and‘forcats’)• ‘sp’ (1.4-1)• ‘amt’ (0.1.3)• ‘lubridate’ (1.7.4)• ‘adehabitatHR’ (0.4.16)1• ‘mefa4’ (0.3-6)• ‘randomForest’ (4.6-14)0. InputsThese are meant to be modified by the analyst to reflect differences in data collection,species biology, etc.• projection: Coordinate reference system for generating SpatialPoints objects fromcoordinates• fix.rate: Temporal resolution (in hours) for GPS collar (i.e. 13)• temp.tol: Temporal tolerance (in hours) for resampling (deviation from fix rate,within which locations are still considered consecutive)• sl.period: Window size (in days) for example mean step length calculation• mcp.period: Window size (in days) for example minimum convex polygon (MCP)calculation• start.date: POSIXct object indicating the beginning of the study period• end.date: POSIXct object indicating the end of the study period# define projectionprojection <- CRS("+proj=utm +zone=17 +ellps=GRS80 +units=m +no_defs")# expected collar sampling rate (in h)fix.rate <- 13# temporal tolerance (in h; how many h +/- the sampling rate# should be considered consecutive?)temp.tol <- 1# window size (in days) for mean step length# (how many days shold be included for calculations?)sl.period <- 3# window size (in days) for minimum convex polygonmcp.period <- 7# time zonetime.zone <- "America/New_York"2# beginning of study periodstart.date <- as.POSIXct("2021-05-15 00:00:00", tz = time.zone)# end of study periodend.date <- as.POSIXct("2021-07-15 23:59:59", tz = time.zone)1. Raw data cleaningThis workflow requires GPS relocation data with five variables: a planar x-coordinate (nu-meric), a planar y-coordinate (numeric), a timestamp (POSIXct), a burst identifier (inte-ger), and an individual identifier (factor). This format is simple to generate using the ‘amt’package (Signer et al. 2020), which we demonstrate in the attached script. We includeda practice dataset (all_data.csv) of 50 simulated animal trajectories generated with thesimm.crw function in ‘adehabitatLT’ (Calenge 2019a), with a h parameter of 300 and an rparameter of 0. We simulated tracks across a 6-month period with a sampling rate of 13hours (yielding 335 locations), and randomly censored 10% of the generated relocations,corresponding to a fix acquisition success/probable location retention rate of 90%.The simulated dataset includes the following variables:• x: Planar x-coordinate (i.e. UTM easting)• y: Planar y-coordinate (i.e. UTM northing)• t: Timestamp with format yyyy-mm-dd hh:mm:ss• AnimalID: Unique individual identifierGPS data should be screened for improbable/inaccurate locations before beginningmove-ment metric generation and analysis. For the purposes of this script, we demonstratehow to calculate mean step lengths and MCPs across pre-defined periods. Because steplength calculation assumes a consistent sampling (fix) rate, it is critical that the temporaltolerance used during track resampling is reasonable (no more than a few hours) to notaffect inference.# read in dataraw.data <- read.csv("all_data.csv")# only keep columns we needraw.data <- raw.data %>% dplyr::select(x, y, t, AnimalID)# make sure "t" is a POSIXct variableraw.data$t <- as.POSIXct(raw.data$t)3# vector of AnimalIDsanimal.ids <- unique(raw.data$AnimalID)# create burstsall.data <- data.frame()for (y in animal.ids) {indivID <- y# subset dataindiv.data <- raw.data %>% filter(AnimalID == indivID)# make a trackindiv.track <- indiv.data %>% make_track(x, y, t, all_cols = TRUE)# create "burst_" column (resample to fix rate +/- tolerance)indiv.track.res <- indiv.track %>%track_resample(rate = hours(fix.rate),tolerance = hours(temp.tol))# bind to "all.data" data.frameall.data <- rbind(all.data, indiv.track.res)}2. Moving window mean step lengthWe used step length, the planar distance between two relocations, averaged over a multi-day window, in this demonstration. First, we converted individual relocation data withburst identifiers to a track and calculated step lengths within bursts with steps_by_burstin ‘amt’. We retained all steps beginning on focal days and additional days needed tocalculate mean step length within our window size (three days in this example), acrossthe entire study period (we chose 15 May–15 Jul, the same as in our study). We addeda day of the year variable (DOY) to increase ease of calculation over the windows. Wethen subset three-day windows iteratively within each individual, calculating the mean steplength for all steps beginning on those days.all.steps <- data.frame()for (z in unique(all.data$AnimalID)) {indivID.2 <- z4# subset all.dataindiv.data.2 <- all.data %>% filter(AnimalID == indivID.2)# create a trackindiv.track.2 <- indiv.data.2 %>% make_track(x_, y_, t_, all_cols = TRUE)# generate stepsindiv.steps <- indiv.track.2 %>% steps_by_burst()# determine how many days before and after period# we need to keep based upon the window sizebuffer.days <- (sl.period - 1) / 2# filter steps across study periodindiv.steps.1 <- indiv.steps %>% filter(t1_ < (end.date +buffer.days*24*60*60) &t1_ >= (start.date -buffer.days*24*60*60))# create a day of the year variableday.seq <- seq(start.date, end.date, by = 24*60*60)# note that we add an extra day because of Daylight Saving Time in the USDOY.seq <- as.integer(difftime(day.seq,as.POSIXct("2021-01-01 00:00:00",tz = time.zone),units = "days") + 2)# add a "DOY" variable to the steps tibbleindiv.steps.2 <- indiv.steps.1 %>%mutate(DOY = as.integer(difftime(t1_,as.POSIXct("2021-01-01 00:00:00",tz = time.zone),units = "days") + 2))# compute mean step length within a 3-day moving windowindiv.steps.2.summary <- data.frame()# for loop which calculates 3-day averages of average daily slfor (w in DOY.seq) {# subset datafocal.steps <- indiv.steps.2 %>% filter(DOY %in% c(w - buffer.days,w,5w + buffer.days))# calculate mean sl for focal periodfocal.mean <- mean(focal.steps$sl_, na.rm = TRUE)# bind into a df with the DOYfocal.summary <- data.frame(Animal = indivID.2,sl.3day = focal.mean,DOY = w)# bind to master dfindiv.steps.2.summary <- rbind(indiv.steps.2.summary,focal.summary)}# bind to master dfall.steps <- rbind(all.steps, indiv.steps.2.summary)}3. Moving window MCPsOur second example variable was the area of a minimum convex polygon (MCP) in km2within a 7-day moving window. We retained the required relocations (study period andadditional relocations needed to calculate MCPs) and generated SpatialPoints objects foreach window, then used the mcp.area function in ‘adehabitatHR’ (Calenge 2019b) to fitMCPs. Choosing the temporal window size for calculating MCPs is important because (1)too wide a windowmay fail to capture temporary space use contractions and (2) too narrowa window may lead to extensive data gaps because at least 5 relocations are required tofit an MCP).all.mcps <- data.frame()for (v in unique(all.data$AnimalID)) {indivID.3 <- v# subset all.data to individualindiv.data.3 <- all.data %>% filter(AnimalID == indivID.3)# subset for study period +/- days needed for calculationsmcp.days <- (mcp.period - 1) / 26indiv.data.4 <- indiv.data.3 %>% filter(t_ < (end.date + mcp.days*24*60*60) &t_ >= (start.date - mcp.days*24*60*60))# create a DOY column (as in part 2)indiv.data.4 <- indiv.data.4 %>%mutate(DOY = as.integer(difftime(t_,as.POSIXct("2021-01-01 00:00:00",tz = time.zone),units = "days") + 2))# calculate 100% MCP areas and add to data frameWin.MCP <- data.frame(MCP = NA,DOY = DOY.seq)for (p in DOY.seq) {# define relocations for moving window pindiv.data.5 <- indiv.data.4 %>% dplyr::filter(DOY >= (p - mcp.days) &DOY <= (p + mcp.days))# fit MCP to relocationsfocal.sp <- SpatialPoints(coords = indiv.data.5[ ,c("x_", "y_")],proj4string = projection)# fit an MCP (use an NA if there are not enough relocations)focal.mcp <- ifelse(nrow(focal.sp@coords) > 4,mcp.area(focal.sp,percent = 100,unin = "m",unout = "km2",plotit = FALSE),NA)Win.MCP$MCP[Win.MCP$DOY == p] <- ifelse(is.na(focal.mcp) == FALSE,focal.mcp[[1]],focal.mcp)}# add CollarID and bind to master data frameWin.MCP <- Win.MCP %>% mutate(Animal = indivID.3)# bind to master dfall.mcps <- rbind(all.mcps, Win.MCP)7}# merge steps and MCPs dfsall.metrics <- merge(all.steps, all.mcps)4. Add in “Case” variable from confirmed parturition datesIn our simulated dataset, we included “confirmed” parturition dates in an auxiliary file(part_dates.csv), and in this section of the code we added these dates to the masterdataset and generated a “Case” variable (where 1 = parturition day and 0 = non-parturitionday), which serves as the response variable in the random forest model. More sophisti-cated models could be trained to classify both the day of parturition and any number ofperipheral days during which movement patterns may also be contracted.# read in parturition dates filepart.dates <- read.csv("part_dates.csv")all.metrics.2 <- data.frame()for (q in unique(all.metrics$Animal)) {indivID.4 <- q# subset individual's parturition dateindiv.date <- part.dates$DOY[part.dates$Animal == indivID.4]# subset individual's data only and add a "Case" column (0 or 1)indiv.metrics <- all.metrics %>% filter(Animal == indivID.4) %>%mutate(Case = ifelse(DOY == indiv.date,1,0))# bind to master dfall.metrics.2 <- rbind(all.metrics.2, indiv.metrics)}5. Examine distributions of predictors based upon CaseWe also include code for simple density plots illustrating the difference in predictor variabledistribution depending upon “Case”. Visually, densities for mean step length appear to be8considerably different between parturition days (1) and non-parturition days (0), indicatingthat this may be an important variable in the random forest classification.# sl.3dayggplot(data = all.metrics.2, aes(x = sl.3day)) +theme_bw() +geom_density(aes(fill = as.factor(Case)),alpha = 0.5)0.00000.00250.00500.00750 250 500 750 1000sl.3daydensityas.factor(Case)01# mcpggplot(data = all.metrics.2, aes(x = MCP)) +theme_bw() +geom_density(aes(fill = as.factor(Case)),alpha = 0.5)90.00.30.60.91.20 1 2MCPdensityas.factor(Case)016. Random forest classificationHere we fit an RF with 1000 decision trees, specified to classify observations as either1s or 0s (Case). We also specified a balanced sample size of 50 parturition and 50 non-parturition days because RFs may perform poorly if the number of observations in eachclass is heavily skewed to one class (which is the case here; there are far more non-parturition days than parturition days).# train RF modelrf.model <- randomForest(as.factor(Case) ~ sl.3day + MCP,na.action = na.omit,sampsize = c(50, 50),ntree = 1000,data = all.metrics.2)When assessing variable importance (mean decrease in the Gini index), it is clear that themean step length variable is much more useful in classifying observations than the MCPvariable.10# assess variable importanceimportance(rf.model, type = 2)## MeanDecreaseGini## sl.3day 41.831971## MCP 8.167029We also generated predictions for each focal day per individual. Because we did notbuild a contraction in movements into our simulated random walks, and simply chose our“confirmed” parturition dates as those with the minimum mean step length within eachindividual, predicted probability peaks are abrupt and brief, which should not be expectedin real-life datasets.# generate predictions for each focal day in the time seriespredictions <- as.data.frame(predict(rf.model, type = "prob"))pred.prob <- predictions[ ,2]# subset only the complete cases (i.e. rows without NA values for predictors)all.metrics.complete <- all.metrics.2[complete.cases(all.metrics.2), ]# bind probabilities to complete casesall.metrics.complete <- cbind(all.metrics.complete, pred.prob)# plot all time seriesggplot(data = all.metrics.complete, aes(DOY, pred.prob)) +theme_bw() +facet_wrap(~Animal) +geom_point(color = "darkgreen", alpha = 0.5) +ylab("") +xlab("") +ggtitle("Probability time series")1149 5041 42 43 44 45 46 47 4833 34 35 36 37 38 39 4025 26 27 28 29 30 31 3217 18 19 20 21 22 23 249 10 11 12 13 14 15 161 2 3 4 5 6 7 8140 160 180 140 160 180140 160 180 140 160 180 140 160 180 140 160 180 140 160 180 140 160 1800.000.250.500.751.000.000.250.500.751.000.000.250.500.751.000.000.250.500.751.000.000.250.500.751.000.000.250.500.751.000.000.250.500.751.00Probability time seriesConclusionsOnce a model is trained, test datasets and predictions can be generated using the sameprocedures outlined in this workflow. Analysts may want to calculate a suite of predictorvariables for varying focal period sizes (Berg et al. 2021, Marchand et al. 2021) rather thanjust one day like we used here and in our study on elk. We believe our workflow is easilytransferrable and augmentable to fit other study systems, species, and data collectionschemes, and may be useful to management agencies interested in identifying ungulateparturition success.12ReferencesBerg, J. E., J. Reimer, P. Smolko, H. Bohm, M. Hebblewhite, and E. H. Merrill. 2021.Mothers’ movements: shifts in calving area selection by partially migratory elk. Journal ofWildlife Management 85:1476–1489.Calenge, C. 2019a. “adehabitatLT”: Analysis of animal movements. R package v. 0.3.24.Calenge, C. 2019b. “adehabitatHR”: Home range estimation. R package v. 0.4.16.Marchand, P., M. Garel, N. Morellet, L. Benoit, Y. Chaval, C. Itty, E. Petit, B. Cargnelutti,A. J. M. Hewison, and A. Loison. 2021. A standardised biologging approach to infer par-turition: An application in large herbivores across the hider￿follower continuum. Methodsin Ecology and Evolution 12:1017–1030.Signer, J., B. Reineking, U. E. Schlägel, and S. LaPoint. 2020. “amt”: Animal movementtools. R package v. 0.1.3.13

Using Low-Fix Rate GPS Telemetry to Expand Estimates of Ungulate Reproductive Success

https://uknowledge.uky.edu/cgi/viewcontent.cgi?filename=1&article=1048&context=forestry_facpub&type=additional

Using Low-Fix Rate GPS Telemetry to Expand Estimates of Ungulate Reproductive Success

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University of Kentucky