Smoothing Population Size Estimates for Time‐Stratified Mark–Recapture Experiments Using Bayesian P‐Splines
Abstract
Summary Petersen‐type mark–recapture experiments are often used to estimate the number of fish or other animals in a population moving along a set migration route. A first sample of individuals is captured at one location, marked, and returned to the population. A second sample is then captured farther along the route, and inferences are derived from the numbers of marked and unmarked fish found in this second sample. Data from such experiments are often stratified by time (day or week) to allow for possible changes in the capture probabilities, and previous methods of analysis fail to take advantage of the temporal relationships in the stratified data. We present a Bayesian, semiparametric method that explicitly models the expected number of fish in each stratum as a smooth function of time. Results from the analysis of historical data from the migration of young Atlantic salmon (Salmo salar) along the Conne River, Newfoundland, and from a simulation study indicate that the new method provides more precise estimates of the population size and more accurate estimates of uncertainty than the currently available methods.
Citing Literature
Number of times cited according to CrossRef: 9
- Dalton J. Hance, Russell W. Perry, John M. Plumb, Adam C. Pope, A temporally stratified extension of space‐for‐time Cormack–Jolly–Seber for migratory animals, Biometrics, 10.1111/biom.13171, 76, 3, (900-912), (2019).
- Dustin L.M. Harper, Julie Horrocks, Jessica Barber, Gale A. Bravener, Carl J. Schwarz, Robert L. McLaughlin, An evaluation of statistical methods for estimating abundances of migrating adult sea lamprey, Journal of Great Lakes Research, 10.1016/j.jglr.2018.08.004, (2018).
- Skip McKinnell, Modelling salmon migration as a mixture problem, Canadian Journal of Fisheries and Aquatic Sciences, 10.1139/cjfas-2017-0546, (1-15), (2018).
- Xiang‐Nan Feng, Guo‐Chang Wang, Yi‐Fan Wang, Xin‐Yuan Song, Structure detection of semiparametric structural equation models with Bayesian adaptive group lasso, Statistics in Medicine, 10.1002/sim.6410, 34, 9, (1527-1547), (2015).
- Laura Cowen, Wendell Challenger, Carl Schwarz, What Do Salmon and Injection Drug Users Have in Common?, Statistics in Action, 10.1201/b16597, (2014).
- Carl James Schwarz, Scott Cope, Glenda Fratton, Integrating batch marks and radio tags to estimate the size of a closed population with a movement model, Ecology and Evolution, 10.1002/ece3.876, 3, 15, (5023-5030), (2013).
- Suresh Andrew Sethi, Theresa L. Tanner, Bayesian implementation of a time stratified Lincoln–Petersen estimator for salmon abundance in the upper Matanuska River, Alaska, USA, Fisheries Research, 10.1016/j.fishres.2013.02.004, 145, (90-99), (2013).
- Richard Huggins, Jakub Stoklosa, Semiparametric inference for open populations using the Jolly–Seber model: a penalized spline approach, Journal of Statistical Computation and Simulation, 10.1080/00949655.2012.668908, 83, 9, (1741-1755), (2013).
- Jean Martin, Gilles Bareille, Sylvain Berail, Christophe Pécheyran, François Gueraud, Frédéric Lange, Françoise Daverat, Noëlle Bru, Eddy Beall, David Barracou, Olivier Donard, Persistence of a southern Atlantic salmon population: diversity of natal origins from otolith elemental and Sr isotopic signatures, Canadian Journal of Fisheries and Aquatic Sciences, 10.1139/cjfas-2012-0284, 70, 2, (182-197), (2013).
