Using Decision Science for Monitoring Threatened Western Snowy Plovers to Inform Recovery
Abstract
:Simple Summary
Abstract
1. Introduction
2. Materials and Methods
2.1. Framing the Decision Problem and Identifying Objectives
2.2. Alternative Monitoring Strategies and Consequences
2.3. Evaluating Tradeoffs Using Objective Weights and Risk Attitudes
2.4. Analysis of Team Scores
2.5. Sensitivity Analysis of Sampling Strategies
2.6. Summary and Presentation of Final Results
3. Results
3.1. Monitoring Sampling Strategies
3.2. Scoring of Monitoring Strategies by Objectives
3.3. Pareto Efficiency and Multi-Attribute Utility
3.4. Sensitivity of Monitoring Strategies to Objective Weights
4. Discussion
- Maintaining individual field journals during the breeding season.
- After the field season, compiling field notes into “nest cards” (individual nest histories) and a banding database, should banding of birds be conducted.
- Implementing quality control of denoting nest GPS locations, by reviewing maps for the final seasonal report.
- Maintaining field equipment including main vehicles, trailers, off-road and all-terrain vehicles, optics, cameras, exclosure fencing, and other gear.
- Preparing an annual field season monitoring report for presentation at the wide-range recovery meeting.
- Coordinating with other institutions and agencies, such as Wildlife Services, on a regular basis to report predator observations and predation events.
- In addition, coordinating with funding partners, including answering questions, attending meetings, and alerting land management agencies of unusual predator or violation activities.
5. Conclusions
Supplementary Materials
Author Contributions
Funding
Institutional Review Board Statement
Acknowledgments
Conflicts of Interest
References
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Objective Weight Scenario | |||
---|---|---|---|
Monitoring Objective | Performance Measure | “Equal” | “More on Mandates” |
1. * Maximize accuracy adult population size | Accuracy: Bias and precision | 0.167 | 0.267 |
2. * Maximize accuracy fledging productivity | Accuracy: Bias and precision | 0.167 | 0.267 |
3. Maximize accuracy of annual survival | Accuracy: Bias and precision | 0.167 | 0.067 |
4. Maximize understanding of nest fate | |||
4.1 Maximize accuracy of nest success | Accuracy: Bias and precision | 0.056 | 0.022 |
4.2 Minimize percent failures unknown | Effectiveness: Identifying causes of nest failures | 0.056 | 0.022 |
4.3 Minimize % of predation unidentified | Effectiveness: Apportioning sources of nest predation | 0.056 | 0.022 |
5. Maximize information transfer to managers | |||
5.1 Maximize Actionable Info.: Timeliness | Frequency of reports to managers | 0.083 | 0.033 |
5.2 Maximize Actionable Info.: Availability | Type of report to managers | 0.083 | 0.033 |
6. Minimize cost | Relative cost | 0.167 | 0.267 |
Total | 1.0 | 1.0 |
Monitoring Strategy | Population Size | Fledgling Productivity a | Annual Survival | Nest Fate | Communicate Information to Managers |
---|---|---|---|---|---|
A. Partially Marked Population (> 50%) | Multiple breeding window surveys at set time intervals. N-mixture models used to correct counts. | Band sample of chicks at each site. | Repeated counts of unmarked individuals with some mark-recapture. | Monitor a sample of nests across time and space, physically examine every 3 days. Use nest cameras to identify predators. | Weekly conference call. |
B. Varied Population Sizes | Multiple breeding window surveys. Banded breeder adjusted with nest ownership. | At large sites, band a random sample of chicks; at small sites, band all chicks. | Periodic mark-resight at banding sites. | Monitor sample of nests at sites where λ < 1 b Use nest cameras to identify predators. | Ad-hoc conference calls with managers. |
C. Variable Plover Densities and Management Needs | Multiple breeding window surveys. | Band a sample of chicks; weekdays only to reduce disturbance. | Repeated unmarked counts with mark-recapture. | Monitor every nest sample at sites c with ≤4 pairs, physically check some at least every 3 days, others > every 3 days. Use nest cameras to identify predators. | Weekly and ad-hoc conference calls. |
D. Minimal I Marked Population | Multiple breeding window surveys. | Band a subset of chicks on sites where the regional λ < 1. | Repeated counts of unmarked individuals. Model survivorship with open population N-mixture models. | Monitor sample based on environmental factors and/or λ < 1, at least every 3 days. Use nest cameras to identify predators. | Weekly report at sites where λ < 1. |
E. Minimal II Effort/Resources | Multiple breeding window surveys. | Band subset of chicks where λ < 1. | Do not monitor. | Sample of nests at least every 3 days. | Monthly report. |
F. Marked Individuals | Banded breeder adjusted with counts. | Band a sample of chicks (all individuals at a subset of dedicated sites). | Mark-resight, banding all individuals at a subset of dedicated banding sites. | Monitor a sample of all nests across time and space. | Combination of individual and daily, weekly, monthly, and ad-hoc conference calls; also preparation and distribution of weekly, monthly, annual, and ad-hoc monitoring reports. |
G. Marked Population | Peak count of nests and broods. Banded breeder adjusted with counts. | Attempt to band all chicks within the study area. | Mark-resight, banding all individuals. | Monitor every nest at least every 3 days. No cameras. | Combination of daily, weekly, monthly, and ad-hoc conference call; also annual and weekly reports. |
H. Mostly Marked Population | Banded breeder adjusted with counts. | Band sample of chicks. | Mark-resight, banding a subset determined through power analysis. | Monitor every nest at intervals > every 3 days. Use nest cameras to identify predators. | Daily communication with individuals. |
I. Nest Focused | Peak count of nests and broods. | Calculate average fledging rate based on number of chicks hatched. | Repeated occupancy surveys. Model survivorship using dynamic N-occupancy models. | Monitor every nest at least every 3 days. Use nest cameras to identify predators. | Monthly conference call with weekly and annual reports. |
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Marcot, B.G.; Lyons, J.E.; Elbert, D.C.; Todd, L. Using Decision Science for Monitoring Threatened Western Snowy Plovers to Inform Recovery. Animals 2021, 11, 569. https://doi.org/10.3390/ani11020569
Marcot BG, Lyons JE, Elbert DC, Todd L. Using Decision Science for Monitoring Threatened Western Snowy Plovers to Inform Recovery. Animals. 2021; 11(2):569. https://doi.org/10.3390/ani11020569
Chicago/Turabian StyleMarcot, Bruce G., James E. Lyons, Daniel C. Elbert, and Laura Todd. 2021. "Using Decision Science for Monitoring Threatened Western Snowy Plovers to Inform Recovery" Animals 11, no. 2: 569. https://doi.org/10.3390/ani11020569
APA StyleMarcot, B. G., Lyons, J. E., Elbert, D. C., & Todd, L. (2021). Using Decision Science for Monitoring Threatened Western Snowy Plovers to Inform Recovery. Animals, 11(2), 569. https://doi.org/10.3390/ani11020569