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Scaling pattern of occupancy

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In spatial ecology and macroecology, scaling pattern of occupancy (SPO), also known as the area-of-occupancy (AOO) is the way in which species distribution changes across spatial scales. In physical geography and image analysis, it is similar to the modifiable areal unit problem. Simon A. Levin (1992)[1] states that the problem of relating phenomena across scales is the central problem in biology and in all of science. Understanding the SPO is thus one central theme in ecology.

Pattern description

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This pattern is often plotted as log-transformed grain (cell size) versus log-transformed occupancy. Kunin (1998)[2] presented a log-log linear SPO and suggested a fractal nature for species distributions. It has since been shown to follow a logistic shape, reflecting a percolation process. Furthermore, the SPO is closely related to the intraspecific occupancy-abundance relationship. For instance, if individuals are randomly distributed in space, the number of individuals in an α-size cell follows a Poisson distribution, with the occupancy being Pα = 1 − exp(−μα), where μ is the density.[3] Clearly, Pα in this Poisson model for randomly distributed individuals is also the SPO. Other probability distributions, such as the negative binomial distribution, can also be applied for describing the SPO and the occupancy-abundance relationship for non-randomly distributed individuals.[4]

Other occupancy-abundance models that can be used to describe the SPO includes Nachman's exponential model,[5] Hanski and Gyllenberg's metapopulation model,[6] He and Gaston's[7] improved negative binomial model by applying Taylor's power law between the mean and variance of species distribution,[8] and Hui and McGeoch's droopy-tail percolation model.[9] One important application of the SPO in ecology is to estimate species abundance based on presence-absence data, or occupancy alone.[10] This is appealing because obtaining presence-absence data is often cost-efficient. Using a dipswitch test consisting of 5 subtests and 15 criteria, Hui et al.[11] confirmed that using the SPO is robust and reliable for assemblage-scale regional abundance estimation. The other application of SPOs includes trends identification in populations, which is extremely valuable for biodiversity conservation.[12]

Explanation

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Models providing explanations to the observed scaling pattern of occupancy include the fractal model, the cross-scale model and the Bayesian estimation model. The fractal model can be configured by dividing the landscape into quadrats of different sizes,[13][14] or bisecting into grids with special width-to-length ratio (2:1),[15][16] and yields the following SPO:

where D is the box-counting fractal dimension. If during each step a quadrat is divided into q sub-quadrats, we will find a constant portion (f) of sub-quadrats is also present in the fractal model, i.e. D = 2(1 + log ƒ/log q). Since this assumption that f is scale independent is not always the case in nature,[17] a more general form of ƒ can be assumed, ƒ = qλ (λ is a constant), which yields the cross-scale model:[18]

The Bayesian estimation model follows a different way of thinking. Instead of providing the best-fit model as above, the occupancy at different scales can be estimated by Bayesian rule based on not only the occupancy but also the spatial autocorrelation at one specific scale. For the Bayesian estimation model, Hui et al.[19] provide the following formula to describe the SPO and join-count statistics of spatial autocorrelation:

where Ω = p(a)0 − q(a)0/+p(a)+ and  = p(a)0(1 − p(a)+2(2q(a)+/+ − 3) + p(a)+(q(a)+/+2 − 3)). p(a)+ is occupancy; q(a)+/+ is the conditional probability that a randomly chosen adjacent quadrat of an occupied quadrat is also occupied. The conditional probability q(a)0/+ = 1 − q(a)+/+ is the absence probability in a quadrate adjacent to an occupied one; a and 4a are the grains. The R-code of the Bayesian estimation model has been provided elsewhere. The key point of the Bayesian estimation model is that the scaling pattern of species distribution, measured by occupancy and spatial pattern, can be extrapolated across scales. Later on, Hui[20] provides the Bayesian estimation model for continuously changing scales:

where b, c, and h are constants. This SPO becomes the Poisson model when b = c = 1. In the same paper, the scaling pattern of join-count spatial autocorrelation and multi-species association (or co-occurrence) were also provided by the Bayesian model, suggesting that "the Bayesian model can grasp the statistical essence of species scaling patterns."

Implications for biological conservation

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The probability of species extinction and ecosystem collapse increases rapidly as range size declines. In risk assessment protocols such as the IUCN Red List of Species or the IUCN Red List of Ecosystems, area of occupancy (AOO) is used as a standardized, complementary and widely applicable measure of risk spreading against spatially explicit threats.[21][22]

References

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  1. ^ Levin, SA. 1992. The problem of pattern and scale in ecology. Ecology, 73, 1943–1967.[1]
  2. ^ Kunin, WE. 1998. Extrapolating species abundance across spatial scales. Science, 281: 1513–1515.[2]
  3. ^ Wright, D.H. 1991. Correlations between incidence and abundance are expected by chance. Journal of Biogeography, 18: 463–466.[3]
  4. ^ He, F., Gaston, K.J. 2000. Estimating species abundance from occurrence. American Naturalist, 156: 553–559.[4]
  5. ^ Nachman, G. 1981. A mathematical model of the functional relationship between density and spatial distribution of a population. Journal of Animal Ecology, 50: 453–460.[5]
  6. ^ Hanski, I., Gyllenberg, M. 1997. Uniting two general patterns in the distribution of species. Science, 284: 334–336.[6]
  7. ^ He, F., Gaston, K.J. 2003. Occupancy, spatial variance, and the abundance of species. American Naturalist, 162: 366–375.[7]
  8. ^ Taylor, L.R. 1961. Aggregation, variance and the mean. Nature, 189: 732–735.[8]
  9. ^ Hui, C., McGeoch, MA. 2007. Capturing the "droopy tail" in the occupancy-abundance relationship. Ecoscience, 14: 103–108.[9]
  10. ^ Hartley, S., Kunin, WE. 2003. Scale dependence of rarity, extinction risk, and conservation priority. Conservation Biology, 17: 1559–1570.
  11. ^ Hui, C., McGeoch, M.A., Reyers, B., le Roux, P.C., Greve, M., Chown, S.L. 2009. Extrapolating population size from the occupancy-abundance relationship and the scaling pattern of occupancy. Ecological Applications, 19: 2038–2048.[10]
  12. ^ Wilson, RJ., Thomas, CD., Fox, R., Roy, RD., Kunin, WE. 2004. Spatial patterns in species distributions reveals biodiversity change. Nature, 432: 393–396.[11]
  13. ^ Hasting, H.M. & Sugihara, G. (1993) Fractals: a User's Guide for the Natural Sciences. Oxford University Press.
  14. ^ Kunin, WE. 1998. Extrapolating species abundance across spatial scales. Science, 281: 1513–1515.
  15. ^ Harte, J., Kinzig, A.P. & Green, J. (1999) Self-similarity in the distribution and abundance of species. Science 294, 334–336.[12]
  16. ^ Hui, C. & McGeoch, M.A. (2007) A self-similarity model for occupancy frequency distributions. Theoretical Population Biology 71: 61–70.[13]
  17. ^ Hui, C. & McGeoch, M.A. (2007) Modeling species distributions by breaking the assumption of self-similarity. Oikos 116: 2097–2107.[14]
  18. ^ Lennon, J.J., Kunin, W.E., Hartley, S. & Gaston, K.J. (2007) Species distribution patterns, diversity scaling and testing for fractals in southern African birds. In: Scaling Biology (D. Storch, P.A. Marquet & J.H. Brown, eds.), pp. 51–76. Cambridge University Press.
  19. ^ Hui, C., McGeoch, M.A. & Warren, M. (2006) A spatially explicitly approach to estimating species occupancy and spatial correlation. Journal of Animal Ecology 75: 140–147.[15]
  20. ^ Hui, C. (2009) On the scaling patterns of species spatial distribution and association. Journal of Theoretical Biology 261: 481–487.[16]
  21. ^ Murray, Nicholas J.; Keith, David A.; Bland, Lucie M.; Nicholson, Emily; Regan, Tracey J.; Rodríguez6,7,8, Jon Paul; Bedward, Michael (2017). "The use of range size to assess risks to biodiversity from stochastic threats". Diversity and Distributions. 23 (5): 474–483. Bibcode:2017DivDi..23..474M. doi:10.1111/ddi.12533. hdl:10536/DRO/DU:30091065.{{cite journal}}: CS1 maint: multiple names: authors list (link) CS1 maint: numeric names: authors list (link)
  22. ^ Murray, Nicholas (2017). "Global 10 x 10-km grids suitable for use in IUCN Red List of Ecosystems assessments (vector and raster format)". Figshare. doi:10.6084/m9.figshare.4653439.v1.