Your search keyword '"Wesley M. Hochachka"' showing total 4 results

1. Modeling avian full annual cycle distribution and population trends with citizen science data

Author

Daniel Fink, Tom Auer, Alison Johnston, Viviana Ruiz‐Gutierrez, Wesley M. Hochachka, and Steve Kelling

Published

2020

2. Modeling avian full annual cycle distribution and population trends with citizen science data

Author

Daniel Fink, Wesley M. Hochachka, Tom Auer, Alison Johnston, Viviana Ruiz-Gutierrez, Steve Kelling, and Frank A. La Sorte

Subjects

0106 biological sciences, Wood Thrush, Occupancy, full annual cycle, Range (biology), Population, Population Dynamics, Bird migration, eBird, 010603 evolutionary biology, 01 natural sciences, Article, population trends, Songbirds, Abundance (ecology), Citizen science, Animals, education, Relative species abundance, Wildlife conservation, education.field_of_study, abundance, biology, Citizen Science, Ecology, 010604 marine biology & hydrobiology, area of occurrence, Articles, biology.organism_classification, Annual cycle, Breeding bird survey, Geography, bird distributions, Wood thrush, biodiversity monitoring, Animal Migration, Seasons, bird migration, Cartography

Abstract

Information on species’ distributions, abundances, and how they change over time is central to the study of the ecology and conservation of animal populations. This information is challenging to obtain at landscape scales across range‐wide extents for two main reasons. First, landscape‐scale processes that affect populations vary throughout the year and across species’ ranges, requiring high‐resolution, year‐round data across broad, sometimes hemispheric, spatial extents. Second, while citizen science projects can collect data at these resolutions and extents, using these data requires appropriate analysis to address known sources of bias. Here, we present an analytical framework to address these challenges and generate year‐round, range‐wide distributional information using citizen science data. To illustrate this approach, we apply the framework to Wood Thrush (Hylocichla mustelina), a long‐distance Neotropical migrant and species of conservation concern, using data from the citizen science project eBird. We estimate occurrence and abundance across a range of spatial scales throughout the annual cycle. Additionally, we generate intra‐annual estimates of the range, intra‐annual estimates of the associations between species and characteristics of the landscape, and interannual trends in abundance for breeding and non‐breeding seasons. The range‐wide population trajectories for Wood Thrush show a close correspondence between breeding and non‐breeding seasons with steep declines between 2010 and 2013 followed by shallower rates of decline from 2013 to 2016. The breeding season range‐wide population trajectory based on the independently collected and analyzed North American Breeding Bird Survey data also shows this pattern. The information provided here fills important knowledge gaps for Wood Thrush, especially during the less studied migration and non‐breeding periods. More generally, the modeling framework presented here can be used to accurately capture landscape scale intra‐ and interannual distributional dynamics for broadly distributed, highly mobile species.

Published

2020

3. Spatiotemporal exploratory models for broad-scale survey data

Author

David W. Winkler, Daniel Fink, Ben Shaby, M. Arthur Munson, Wesley M. Hochachka, Benjamin Zuckerberg, Daniel Sheldon, Steve Kelling, Mirek Riedewald, and Giles Hooker

Subjects

Time Factors, Ecology, Ensemble forecasting, Species distribution, Models, Biological, United States, Semiparametric model, Songbirds, Geography, Species Specificity, Habitat, Abundance (ecology), Animals, Scale (map), Ecosystem, Decision tree model, Environmental Monitoring, Sampling bias

Abstract

The distributions of animal populations change and evolve through time. Migratory species exploit different habitats at different times of the year. Biotic and abiotic features that determine where a species lives vary due to natural and anthropogenic factors. This spatiotemporal variation needs to be accounted for in any modeling of species' distributions. In this paper we introduce a semiparametric model that provides a flexible framework for analyzing dynamic patterns of species occurrence and abundance from broad- scale survey data. The spatiotemporal exploratory model (STEM) adds essential spatiotem- poral structure to existing techniques for developing species distribution models through a simple parametric structure without requiring a detailed understanding of the underlying dynamic processes. STEMs use a multi-scale strategy to differentiate between local and global- scale spatiotemporal structure. A user-specified species distribution model accounts for spatial and temporal patterning at the local level. These local patterns are then allowed to ''scale up'' via ensemble averaging to larger scales. This makes STEMs especially well suited for exploring distributional dynamics arising from a variety of processes. Using data from eBird, an online citizen science bird-monitoring project, we demonstrate that monthly changes in distribution of a migratory species, the Tree Swallow (Tachycineta bicolor), can be more accurately described with a STEM than a conventional bagged decision tree model in which spatiotemporal structure has not been imposed. We also demonstrate that there is no loss of model predictive power when a STEM is used to describe a spatiotemporal distribution with very little spatiotemporal variation; the distribution of a nonmigratory species, the Northern Cardinal (Cardinalis cardinalis).

Published

2010

4. A characterization of autumn nocturnal migration detected by weather surveillance radars in the northeastern US

Author

Steve Kelling, Wesley M. Hochachka, Jeffrey Geevarghese, Jed Irvine, Andrew Farnsworth, Benjamin M. Van Doren, Daniel Sheldon, and Kevin Winner

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, Bird migration, Wind, Nocturnal, 010603 evolutionary biology, 01 natural sciences, law.invention, Birds, New England, law, Animals, Precipitation, Radar, Weather, 0105 earth and related environmental sciences, Population Density, Ecology, Phenology, Altitude, Reflectivity, Circadian Rhythm, Climatology, Environmental science, Animal Migration, Seasons, Environmental Monitoring

Abstract

Billions of birds migrate at night over North America each year. However, few studies have described the phenology of these movements, such as magnitudes, directions, and speeds, for more than one migration season and at regional scales. In this study, we characterize density, direction, and speed of nocturnally migrating birds using data from 13 weather surveillance radars in the autumns of 2010 and 2011 in the northeastern USA. After screening radar data to remove precipitation, we applied a recently developed algorithm for characterizing velocity profiles with previously developed methods to document bird migration. Many hourly radar scans contained windborne "contamination," and these scans also exhibited generally low overall reflectivities. Hourly scans dominated by birds showed nightly and seasonal patterns that differed markedly from those of low reflectivity scans. Bird migration occurred during many nights, but a smaller number of nights with large movements of birds defined regional nocturnal migration. Densities varied by date, time, and location but peaked in the second and third deciles of night during the autumn period when the most birds were migrating. Migration track (the direction to which birds moved) shifted within nights from south-southwesterly to southwesterly during the seasonal migration peaks; this shift was not consistent with a similar shift in wind direction. Migration speeds varied within nights, although not closely with wind speed. Airspeeds increased during the night; groundspeeds were highest between the second and third deciles of night, when the greatest density of birds was migrating. Airspeeds and groundspeeds increased during the fall season, although groundspeeds fluctuated considerably with prevailing winds. Significant positive correlations characterized relationships among bird densities at southern coastal radar stations and northern inland radar stations. The quantitative descriptions of broadscale nocturnal migration patterns presented here will be essential for biological and conservation applications. These descriptions help to define migration phenology in time and space, fill knowledge gaps in avian annual cycles, and are useful for monitoring long-term population trends of migrants. Furthermore, these descriptions will aid in assessing potential risks to migrants, particularly from structures with which birds collide and artificial lighting that disorients migrants.

Published

2015