Refurbishing Used GPS Transmitters Improves Performance for Subsequent Deployments on Greater Sage-Grouse

Authors

Melissa S. Chelak, Utah State UniversityFollow
Michel T. Kohl, University of Georgia
Justin R. Small, Nevada Department of Wildlife
Kurt T. Smith, University of Wyoming
Aaron C. Pratt, University of Wyoming
Jeffrey L. Beck, University of Wyoming
Codi R. Backen, Utah State University
M. Brandon Flack, Idaho Department of Fish and Game
Hailey P. Wayment, Utah State University
Jason A. Wood, Brigham Young University
Ryan Howell, Brigham Young University
Trevon D. Strange, Utah State University
Lucian R. McDonald, Utah State University
Kezia R. Manlove, Utah State University
Shandra N. Frey, Utah State University
Randy T. Larsen, Brigham Young University
Brian A. Maxfield, Utah Division of Wildlife Resources
David K. Dahlgren, Utah State University
Terry A. Messmer, Utah State University
David C. Stoner, Utah State UniversityFollow

Document Type

Article

Journal/Book Title/Conference

Wildlife Society Bulletin

Author ORCID Identifier

Melissa S. Chelak https://orcid.org/0000-0003-4497-7713

Michel T. Kohl https://orcid.org/0000-0001-8218-1455

Jeffrey L. Beck https://orcid.org/0000-0003-0236-7343

Volume

49

Issue

1

Publisher

John Wiley & Sons, Inc.

Publication Date

1-16-2025

Journal Article Version

Version of Record

First Page

1

Last Page

19

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 License.

Abstract

Global Positioning Systems (GPS) radio transmitters are increasingly used across taxa to monitor animal populations. However, GPS transmitters can be susceptible to malfunctions that may result in location errors or data loss causing potential inferential bias that can have important implications for monitored species. Research using GPS transmitters on greater sage-grouse (Centrocercus urophasianus; sage-grouse) has increased, but few sage-grouse studies have evaluated GPS performance. Because sage-grouse management has been subject to intense legal and political scrutiny with consequential economic implications, reliable data acquisition is central to informed decision-making for the species. We evaluated differences in the performance of 2 commonly used solar-powered GPS transmitters (Microwave Telemetry, Inc. [MTI], Columbia, MD, USA and GeoTrak, Inc., Apex, NC, USA) deployed on sage-grouse throughout Wyoming from 2011 to 2017 and Utah from 2013 to 2019. Our investigation of GPS performance included daily fix inefficiency, the number of 1-day fix gaps, and transmitter loss rate. We also evaluated transmitter functionality during the nesting period including daily nesting fix inefficiency, fix error distance mean and standard deviation (i.e., accuracy and precision), and mean fix error direction. New and refurbished MTI transmitters outperformed GeoTrak transmitters in daily fix inefficiency and day gaps during most seasons. Cumulatively redeployed MTI transmitters did not perform differently than GeoTrak transmitters. Transmitter loss, daily nesting fix inefficiency, and nest fix precision did not vary significantly between the 2 transmitters. GeoTrak performed better than MTI for nest fix accuracy across all latitudes (40–45° N). The mean error direction to the nest location ranged between 105° and 135° for GeoTrak and between 135° and 155° for MTI. We recommend refurbishing transmitters following deployment to retain higher fix efficiency than cumulatively redeploying transmitters.

Recommended Citation

Chelak, M. S., M. T. Kohl, J. R. Small, K. T. Smith, A. C. Pratt, J. L. Beck, C. R. Backen, M. Brandon Flack, H. P. Wayment, J. A. Wood, et al. 2025. Refurbishing used GPS transmitters improves performance for subsequent deployments on greater sage-grouse. Wildlife Society Bulletin 49:e1566. https://doi.org/10.1002/wsb.1566