landscape analysis resm 575 spring 2011 lecture 12
TRANSCRIPT
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Landscape Analysis
RESM 575
Spring 2011
Lecture 12
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Today
Part A Landscape analysis and metrics
Part B Animal movement analysis
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Putting landscape biodiversity in perspective
Stein et al., 2006. Precious Heritage: The Status of Biodiversity in the United States. The Nature Conservancy.
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Landscape (ecologist, env scientist) a conceptual unit for the study of spatial patterns
in the physical environment and the influence of these patterns on important environmental resources.
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5(Theiling, 2006)
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Landscape metrics
Goal is to study the pattern–process relationships
This has resulted in the development of literally hundreds of indices of landscape patterns.
Spatial pattern
Ecological
processes
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Landscape context
Landscapes don’t exist in isolation
They are nested within larger landscapes
Degree of “openness of a system”
EX: from a geomorphological perspective, a watershed is a closed system
EX: for a bird population, a watershed is an open system
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Landscape scale
Most important consideration in an ecological landscape investigation
Must be explicitly defined
Describe patterns or relationships relative to scale
Be extremely cautious when attempting to compare landscapes measured at different scales
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Classes of landscape pattern
Applied to four types of spatial data: Spatial point patterns Linear network patterns Surface patterns Categorical map patterns
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Spatial point patterns
The locations of the points are of primary interest rather than any quantity or quality
Clustered, random, dispersed?
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Linear network patterns
Map of streams or riparian areas and the goal is to characterize the physical structure
Corridor density, connectivity, etc.
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Surface patterns
No explicit boundaries, patches are not delineated, looking for spatial dependencies
Elevation, precipitation, continuous data
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Categorical map patterns
Mosaic of discrete patches, land cover and use
Goal is to characterize the composition and spatial configuration
Most popular and the one we will focus on
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Categorical map patterns
Characterization falls under: Composition
Features associated with the variety and abundance of patch types but not considering the placement, attributes, or location of the patches in the mosaic
Spatial Configuration refers to the spatial character and arrangement,
position, or orientation of patches within the class or landscape.
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Composition example metrics Proportional abundance of each-class.
One of the simplest and perhaps most useful pieces of information that can be derived is the proportion of each class relative to the entire map.
Richness. Simply the number of different patch types.
Eveness The relative abundance of different patch types, typically
emphasizing either relative dominance or its complement, equitability.
Diversity Diversity is a composite measure of richness and evenness and
can be computed in a variety of forms (e.g. Shannon’s, Simpson’s), depending on the relative emphasis placed on these two components
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Spatial configuration example metrics
Characterization falls under Patch size distribution and density
Mean, median, max, variance Patch shape complexity
Simple and compact or irregular and convoluted, perimeter per area unit
Core areas Interior area of patches, integrates patch size, shape,
and edge effect distance into a single measure. All other things being equal, smaller patches with
greater shape complexity have less core area.
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MORE! Spatial configuration example metrics
Characterization falls under Isolation, proximity Contrast Dispersion Contagion Subdivision Connectivity
See link to McGarigal (1999) on website for more info
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What makes a landscape metric useful? A strong relationship between metric and
functional response The metric must pick up changes in the
landscape that are important to a species or ecological process
EX:The black bear requires large intact forest patches of 125 acres or greater where does this habitat currently exist or where is that threshold of 125 acres being approached?
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GIS role in measuring landscapes
Most GISs can calculate the basic metrics All of the more sophisticated metrics use GIS data
as inputs FRAGSTATS
http://www.umass.edu/landeco/research/fragstats/fragstats.html
ATILLA Analytical Tools Interface for Landscape Assessments http://www.epa.gov/nerlesd1/land-sci/attila/
PATCH ANALYST http://flash.lakeheadu.ca/~rrempel/patch/
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Limitations
Metrics are a snapshot in time High degree of correlation among metrics
(patch size, area, core area, edge, etc)
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McGarigal (1999) suggests…
Before selecting a metric:1. Does it represent landscape composition or configuration, or both?
2. What aspect of composition or configuration does it represent?
3. Is it spatially explicit and, if so, at the patch-, class-, or landscape-level?
4. How is it affected by the designation of a matrix element?
5. Does it reflect an island biogeographical or landscape mosaic perspective of landscape pattern?
6. How does it behave or respond to variation in landscape pattern?
7. What is the range of variation in the metric under an appropriate spatiotemporal reference framework?
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Typical landscape metrics Fragmentation
Edge
Core area or interior forest
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Fragstats metrics
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References
Boyce, M.S., and A. Haney. 1997. Ecosystem Management: Applications for Sustainable Forest and Wildlife Resources. Yale University Press, New Haven & London. 361 pages
Forman, R.T. T., and M. Godron. 1986. Landscape Ecology. Wiley, New York. Grumbine, R. E. 1994. What is Ecosystem Management. Conservation Biology8:27-38. Hobbs, R. 1997. Future Landscapes and the Future of Landscape Ecology. Landscape and Urban Planning 37:1-
9. Jones, B.K, K.H. Ritters, J. D. Wickham, R.D. Tankersley, R.V. ONeill, D.J. Chaloud, E. R. Smith, and A.C. Neale.
1997 An Ecological Assessment of United States Mid-Atlantic Region: A Landscape Atlas. Benedic, M. A. and E. T. McMahon. 2000. Green infrastructure: smart conservation for the 21 st century. The
Sprawl Watch Clearinghouse Monograph Series, The Conservation Fund. Grayson, R. B., I. D. Moore, and T. A. McMahon. 1992. Physically based hydrologic modeling: 1. A terrain based
model for investigative purposes. Water Resources Research 28(10):2639-2658. Loehle, C. 1999. Optimizing wildlife habitat mitigation with a habitat defragmentation algorithm. Forest Ecology
and Management 120 (1999) 245-251 Mitasova, H. J. Hofieka, M., Zlocha, L. R. Iverson. 1996. Modeling topographic potential for erosion and
deposition using GIS. International Journal of Geographic Information Systems 10:629-641. Riters, K. H. 1995. A Factor Analysis of Landscape Pattern and Structure Metrics. Landscape Ecology 10:23-39. Wickham, J. D. Jones, K. B. Ritters, K. H. O’Neill, R. V. Tankersley, R. D. Smith, E. R. Neale, A. C. and Chaloud,
D. J. 1999. An integrated environmental assessment of the US Mid-Atlantic Region. Environ Manag 24: 553-560. Wickham, J. D., R. V. O’Neill, and K. B. Jones. 2000. Forest fragmentation as an economic indicator. Landscape
Ecology 15: 171-179. Wiens, J. 1976. 1976. Population responses to patchy environments. Ann. Rev. Ecol Syst. 7:81-120
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Part B.Animal Movement
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Overview
Background on animal movement Hawth’s tools (only for ArcGIS 9.3 now)
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Field studies of animals
Commonly record the locations where individuals are observed.
In many cases these point data, often referred to as "fixes", are determined by radio telemetry.
These data may be used in both "basic" and "applied" contexts.
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Using the point data or “fixes”
Used to test basic hypotheses animal behavior resource use population distribution interactions among individuals and populations.
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Other uses of the point data
Location data may also be used in conservation and management of species.
The problem for researchers is To determine which data points are relevant to
their needs How to best summarize the information.
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Researchers using the point data
Rarely interested in every point that is visited, or the entire area used by an animal during its lifetime.
Focus on the animal's "home range“ "…that area traversed by the individual in its
normal activities of food gathering, mating, and caring for young. (Rogers and Carr, 1998)
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Home range notes
Occasional sallies outside the area, perhaps exploratory in nature, should not be considered as in part of the “home range." (Burt 1943).
Thus, in its simplest form, "home range analysis" involves the delineation of the area in which an animal conducts its "normal" activities.
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To maintain scientific integrity (repeatability)
Objective criteria must be used to select movements that are "normal" (White and Garrott 1990).
The obvious difficulty is in the definition of what should be considered "normal".
Because of this difficulty, there has been a proliferation of home range analysis models.
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Home range models
Minimum convex polygons Bivariate normal models
Jennrich-Turner estimator weighted bivariate normal estimator, multiple ellipses, Dunn estimator
Nonparametric models grid cell counts, Fourier series smoothing, harmonic mean
Contouring models peeled polygons, kernel methods, hierarchical incremental cluster analysis
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Of note:
• However, home range analysis may involve more than just estimating the characteristics of areas occupied by animals.
• Researchers often want to know about the distances, headings, times and speed of animal movements between locations.
• They may also want to assess interactions of animals based on areas of overlap among home ranges or distances between individuals at a particular point in time.
Most of these methods and their limitations have been reviewed by Harris et al. (1990) and White and Garrott (1990).
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Hawth’s tools
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Hawth’s tools
Includes 2 home range analysis models: minimum convex polygons (MCPs) and kernel methods.
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Minimum convex polygons
MCPs do not indicate how intensively different parts of an animal's range are used
Constructed by connecting the peripheral points of a group of points, such that external angles are greater than 180° (Mohr 1947). "Percent" minimum convex polygons "probability polygons" (Kenward 1987), "restricted polygons" (Harris et al. 1990) "mononuclear peeled polygons"
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Kernal methods
Allow determination of centers of activity Kernel analysis is a nonparametric statistical method for
estimating probability densities from a set of points. In the context of home range analysis these methods describe
the probability of finding an animal in any one place. Home range estimates are derived by drawing contour lines (i.e.,
isopleths) based on the volume of the curve under the utilization distribution.
Alternatively, isopleths can be drawn that connect regions of equal kernel density. In either case, the isopleths define home range polygons whose areas can be calculated.
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References
Burt, W. H. 1943. Territoriality and home range concepts as applied to mammals. J. Mammal. 24:346-352.(Harris, S., W. J. Cresswell, P. G. Forde, W. J. Trewhella, T. Woollard, and S. Wray 1990. Home-range
analysis using radio-tracking data - a review of problems and techniques particularly as applied to the study of mammals. Mammal Rev. 20:97-123.
Jones, M. C., J. S. Marron, and S. J. Sheather. 1996. A brief survey of bandwidth selection for density estimation. J. Amer. Stat. Assoc. 91:401-407.
Kenward, R. 1987. Wildlife radio tagging. Academic Press, Inc., London, UK. 222 pp.Kenward, R. E., and K. H. Hodder. 1996. RANGES V: an analysis system for biological location data. Inst.
Terrestrial Ecol., Furzebrook Res. Stn., Wareham, UK. 66 pp.Larkin, R. P., and D. Halkin. 1994. A review of software packages for estimating animal home ranges. Wildl.
Soc. Bull. 22:274-287.Lawson, E. J. G., and A. R. Rodgers. 1997. Differences in home-range size computed in commonly used
software programs. Wildl. Soc. Bull. 25:721-729.Michener, G. R. 1979. Spatial relationships and social organization of adult Richardson's ground squirrels.
Can. J. Zool. 57:125-139..Rodgers, A. R., R. S. Rempel, and K. F. Abraham. 1996. A GPS-based telemetry system. Wildl. Soc. Bull.
24:559-566.Schoener, T. W. 1981. An empirically based estimate of home range. Theor. Pop. Biol. 20:281-325.Seaman, D. E., and R. A. Powell. 1996. An evaluation of the accuracy of kernel density estimators for home
range analysis. Ecology 77:2075-2085.Swihart, R. K., and N. A. Slade. 1985a. Testing for independence of observations in animal movements.
Ecology 66:1176-1184.Swihart, R. K., and N. A. Slade. 1985b. Influence of sampling interval on estimates of home-range size. J.
Wildl. Manage. 49:1019-1025.Worton, B. J. 1989. Kernel methods for estimating the utilization distribution in home-range studies. Ecology
70:164-168.Worton, B. J. 1995. Using Monte Carlo simulation to evaluate kernel-based home range estimators. J. Wildl.
Manage. 59:794-800.