1 / 26

Quantifying Patterns of Biological Diversity using Vertebrate Habitat Models

Quantifying Patterns of Biological Diversity using Vertebrate Habitat Models. Frank A. La Sorte. Acknowledgements. Southwest Regional Gap Analysis Project: Bruce C. Thompson, Kenneth G. Boykin, Scott Schrader, Robert A. Deitner.

xanti
Download Presentation

Quantifying Patterns of Biological Diversity using Vertebrate Habitat Models

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Quantifying Patterns of Biological Diversity using Vertebrate Habitat Models Frank A. La Sorte

  2. Acknowledgements Southwest Regional Gap Analysis Project: Bruce C. Thompson, Kenneth G. Boykin, Scott Schrader, Robert A. Deitner. New Mexico Cooperative Fish and Wildlife Research Unit, New Mexico State University.

  3. Justification • We require tools to quantify large scale patterns of biological diversity • provide information for decision making on large scale environmental issues • Adequately documenting these patterns is inherently difficult • tremendous ecological complexity • lack of time and resources

  4. Justification (continued) • Trade off: • document large scale patterns quickly with limited precision, accuracy, generality, and predictability • Gap analysis presents regional patterns of vertebrate habitat associations within their estimated ranges • However, it lacks well defined methods for: • quantifying diversity • decision making

  5. Objectives • Concept of Ecological Diversity • Dimensions and Components • Quantifying Diversity Patterns within Gap Analysis • Richness, Evenness, Distinctness • Example: 1996 New Mexico Gap Data • New Mexico • Tularosa Basin • Applications for Decision Making

  6. Limitations • Models are subjective, non-probabilistic, and static • Accuracy unknown • Level of error propagation unknown • Variables highly correlated • Qualitative (presence/absence) • Limited to vertebrates • Varying perceptions of scale by species • Habitat is scale dependent • No intra- and interspecific factors • Ignores size and spatial arrangement of patches

  7. Ecological Diversity • Units • Grain • Extent • Diversity patterns • Richness • Evenness • Taxonomic distinctness • Landscape patterns • Time

  8. Distinctness Order Family Evenness Genus Richness Species Diversity Patterns

  9. Vertebrate Habitat Models • Large scale biological and abiotic features, that can be represented cartographically, found within the estimated range of a species • Combined with Boolean AND operators to create a binary grid (presence/absence)

  10. Gap Richness • Definition: quantity of vertebrate habitats within a unit area • Sum all vertebrate habitat models

  11. Richness • Does not predict presence, persistence, fitness, habitat quality, or biodiversity • Interpretation of richness “hotspots” problematic • Not consistent across taxa • Scale dependent • Biased towards marginal populations

  12. Gap Evenness • Definition: How evenly vertebrate habitat is distributed within a taxonomic level in a unit area • Species as the unit of evenness • Summarize evenness trend with principle component analysis

  13. Evenness Metrics • Non-ordered or scalar metrics • Ordered metrics • Information theory (Rényi, Hill) • Cumulative measures (Lorenz curve)

  14. Lorenz Curve Lorenz Curve: (0, 0) (1/s, p1) (2/s, p1 + p2)…(s-1/s, p1 + p2 + … + ps-1) (1, 1) Where the proportions are ranked p1< p2<…< ps for s groups Gini Coefficient: (Area between the Lorenz Curve and the line of equality) x 2

  15. Lorenz Curve

  16. Order Family ω = 1 ω = 2 ΣΣ i<jωij s (s – 1)/2 ω = 3 Δ+ = Genus Species Gap Taxonomic Distinctness • Definition: How taxonomically distinct vertebrate habitat is within a unit area • Measured as the average taxonomic path length for each cell based upon a weighting factor (Clarke & Warwick 1998) Path length weights (ω) Average path length

  17. Example: New Mexico • NM GAP 1996 • 100 x 100 m cells • 346 vertebrate species • 20 Orders • 55 Families • 195 Genera

  18. Example: Tularosa Basin Alamogordo White Sands National Monument Sacramento Mountains 9,369.2 km2

  19. High Low Richness Taxonomic distinctness Evenness Order Family

  20. Correlation Matrix

  21. Application to decision making • Provides more detailed information on the patterns of diversity • multivariate nature of diversity • Use a combination of diversity components with other variables to: • more accurately represent gaps • contrast sites based upon some criteria • locate sites with desired characteristics

  22. Decision Making • Assist in directing policy, research, management, and conservation efforts more efficiently • Should not be the sole source of information • Should be interpreted cautiously and honestly

More Related