Abstract
Estimating riverwide abundance of juvenile fish populations is challenging because detection probability is typically low and juveniles can be patchily distributed over large areas. We used a hierarchical Bayesian model to estimate the abundance of juvenile steelhead Oncorhynchus mykiss in two rivers in British Columbia over 3 years based on a multigear, two-phase sampling design. These estimates were used to drive a simulation model to evaluate how the precision of abundance estimates varied with the number of single-pass index and mark–recapture sites that were sampled, the proportion of shoreline sampled, and the mean and variation of detection probability and fish density across sites. The extent of variation in fish densities across index sites was the most important factor influencing the precision of river-wide abundance estimates, and increasing the number of index sites was the best approach to reduce variability in abundance estimates. River size, which controls the proportion of habitat sampled for a given level of sampling effort, had a moderate effect on precision, but only when the extent of site-to-site variation in fish density was high. Factors affecting detection probability, such as the number of mark–recapture sites, the mean detection probability, or the extent of variation in detection probability across sites, had much less influence on precision of abundance estimates unless the proportion of river sampled was high. Hierarchical Bayesian models are no substitute for collecting informative data, but they improve our understanding of variance structure, which is critical for providing realistic estimates of uncertainty and designing informative and efficient sampling programs.
Received July 16, 2015; accepted October 7, 2015 Published online March 8, 2016
Acknowledgments
This project was supported through a contract from the British Columbia Hydro and Power Authority to Ecometric Research. We thank Lew Coggins, Andrew Gelman, and Robert Dorazio for providing helpful suggestions on the structure of the hierarchal Bayesian model. We thank Mike Stamford, Scott Decker, John Hagen, David Bryan, L. J. Wilson, Heath Zander, and Don McCubbing for assistance in the field and with fish aging. Thanks to Lew Coggins, Scott Decker, and Carl Walters for providing helpful suggestions on an earlier version of the manuscript.