Serengeti wildebeest migratory patterns modeled from rainfall and new vegetation growth

Randall B. Boone; Simon J. Thirgood; J. Grant C. Hopcraft

doi:10.1890/0012-9658(2006)87[1987:SWMPMF]2.0.CO;2

Serengeti wildebeest migratory patterns modeled from rainfall and new vegetation growth

Randall B. Boone^*, Simon J. Thirgood, J. Grant C. Hopcraft

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

We used evolutionary programming to model innate migratory pathways of wildebeest in the Serengeti Mara Ecosystem, Tanzania and Kenya. Wildebeest annually move from the southern short-grass plains of the Serengeti to the northern woodlands of the Mara. We used satellite images to create 12 average monthly and 180 10-day surfaces from 1998 to 2003 of percentage rainfall and new vegetation. The surfaces were combined in five additive and three multiplicative models, with the weightings on rainfall and new vegetation from 0% to 100%. Modeled wildebeest were first assigned random migration pathways. In simulated generations, animals best able to access rainfall and vegetation were retained, and they produced offspring with similar migratory pathways. Modeling proceeded until the best pathway was stable. In a learning phase, modeling continued with the ten-day images in the objective function. The additive model, influenced 25% by rainfall and 75% by vegetation growth, yielded the best agreement, with a multi-resolution comparison to observed densities yielding 76.8% of blocks in agreement (kappa 0.32). Agreement was best for dry season and early wet season (kappa 0.22-0.57), and poorest for the late wet season (0.04). The model suggests that new forage growth is a dominant correlate of wildebeest migration.

Original language	English
Pages (from-to)	1987-1994
Number of pages	8
Journal	Ecology
Volume	87
Issue number	8
DOIs	https://doi.org/10.1890/0012-9658(2006)87[1987:SWMPMF]2.0.CO;2
Publication status	Published - Aug-2006

Keywords

Connochaetes taurinus
evolutionary programming
migration
NDVI
rainfall estimates
Serengeti Mara Ecosystem
wildebeest
LARGE HERBIVORES
NATIONAL-PARK
LAND-USE
BEHAVIOR
ALGORITHMS
TANZANIA
QUALITY

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10.1890/0012-9658(2006)87[1987:SWMPMF]2.0.CO;2

Boone_et_al-2006-EcologyFinal publisher's version, 466 KBLicence: Unspecified

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Appendix B. Locations on the 15th of each month of wildebeest simulated in the evolutionary stage for models influenced by rainfall and new vegetation growth, as reflected in NDVI.
Boone, R. B. (Contributor), Hopcraft, J. (Contributor) & Thirgood, S. J. (Contributor), figshare Academic Research System, 5-Aug-2016
DOI: 10.6084/m9.figshare.3526499.v1
Dataset
Appendix A. Measures of goodness-of-fit for wildebeest pathways from eight objective functions averaged for multiple-resolution comparisons from 5 to 50 km square blocks.
Boone, R. B. (Contributor), Thirgood, S. J. (Contributor) & Hopcraft, J. G. C. (Contributor), figshare Academic Research System, 5-Aug-2016
DOI: 10.6084/m9.figshare.3526502.v1
Dataset
Appendix C. Nine wildebeest migratory pathways that evolved using average monthly surfaces in the additive model and yearly pathways refined in a learning phase.
Boone, R. B. (Contributor), Thirgood, S. J. (Contributor) & Hopcraft, J. G. C. (Contributor), figshare Academic Research System, 5-Aug-2016
DOI: 10.6084/m9.figshare.3526496.v1
Dataset

Cite this

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title = "Serengeti wildebeest migratory patterns modeled from rainfall and new vegetation growth",

abstract = "We used evolutionary programming to model innate migratory pathways of wildebeest in the Serengeti Mara Ecosystem, Tanzania and Kenya. Wildebeest annually move from the southern short-grass plains of the Serengeti to the northern woodlands of the Mara. We used satellite images to create 12 average monthly and 180 10-day surfaces from 1998 to 2003 of percentage rainfall and new vegetation. The surfaces were combined in five additive and three multiplicative models, with the weightings on rainfall and new vegetation from 0% to 100%. Modeled wildebeest were first assigned random migration pathways. In simulated generations, animals best able to access rainfall and vegetation were retained, and they produced offspring with similar migratory pathways. Modeling proceeded until the best pathway was stable. In a learning phase, modeling continued with the ten-day images in the objective function. The additive model, influenced 25% by rainfall and 75% by vegetation growth, yielded the best agreement, with a multi-resolution comparison to observed densities yielding 76.8% of blocks in agreement (kappa 0.32). Agreement was best for dry season and early wet season (kappa 0.22-0.57), and poorest for the late wet season (0.04). The model suggests that new forage growth is a dominant correlate of wildebeest migration.",

keywords = "Connochaetes taurinus, evolutionary programming, migration, NDVI, rainfall estimates, Serengeti Mara Ecosystem, wildebeest, LARGE HERBIVORES, NATIONAL-PARK, LAND-USE, BEHAVIOR, ALGORITHMS, TANZANIA, QUALITY",

author = "Boone, {Randall B.} and Thirgood, {Simon J.} and Hopcraft, {J. Grant C.}",

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language = "English",

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AU - Thirgood, Simon J.

AU - Hopcraft, J. Grant C.

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Y1 - 2006/8

N2 - We used evolutionary programming to model innate migratory pathways of wildebeest in the Serengeti Mara Ecosystem, Tanzania and Kenya. Wildebeest annually move from the southern short-grass plains of the Serengeti to the northern woodlands of the Mara. We used satellite images to create 12 average monthly and 180 10-day surfaces from 1998 to 2003 of percentage rainfall and new vegetation. The surfaces were combined in five additive and three multiplicative models, with the weightings on rainfall and new vegetation from 0% to 100%. Modeled wildebeest were first assigned random migration pathways. In simulated generations, animals best able to access rainfall and vegetation were retained, and they produced offspring with similar migratory pathways. Modeling proceeded until the best pathway was stable. In a learning phase, modeling continued with the ten-day images in the objective function. The additive model, influenced 25% by rainfall and 75% by vegetation growth, yielded the best agreement, with a multi-resolution comparison to observed densities yielding 76.8% of blocks in agreement (kappa 0.32). Agreement was best for dry season and early wet season (kappa 0.22-0.57), and poorest for the late wet season (0.04). The model suggests that new forage growth is a dominant correlate of wildebeest migration.

AB - We used evolutionary programming to model innate migratory pathways of wildebeest in the Serengeti Mara Ecosystem, Tanzania and Kenya. Wildebeest annually move from the southern short-grass plains of the Serengeti to the northern woodlands of the Mara. We used satellite images to create 12 average monthly and 180 10-day surfaces from 1998 to 2003 of percentage rainfall and new vegetation. The surfaces were combined in five additive and three multiplicative models, with the weightings on rainfall and new vegetation from 0% to 100%. Modeled wildebeest were first assigned random migration pathways. In simulated generations, animals best able to access rainfall and vegetation were retained, and they produced offspring with similar migratory pathways. Modeling proceeded until the best pathway was stable. In a learning phase, modeling continued with the ten-day images in the objective function. The additive model, influenced 25% by rainfall and 75% by vegetation growth, yielded the best agreement, with a multi-resolution comparison to observed densities yielding 76.8% of blocks in agreement (kappa 0.32). Agreement was best for dry season and early wet season (kappa 0.22-0.57), and poorest for the late wet season (0.04). The model suggests that new forage growth is a dominant correlate of wildebeest migration.

KW - Connochaetes taurinus

KW - evolutionary programming

KW - migration

KW - NDVI

KW - rainfall estimates

KW - Serengeti Mara Ecosystem

KW - wildebeest

KW - LARGE HERBIVORES

KW - NATIONAL-PARK

KW - LAND-USE

KW - BEHAVIOR

KW - ALGORITHMS

KW - TANZANIA

KW - QUALITY

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DO - 10.1890/0012-9658(2006)87[1987:SWMPMF]2.0.CO;2

M3 - Article

SN - 0012-9658

VL - 87

SP - 1987

EP - 1994

JO - Ecology

JF - Ecology

IS - 8

ER -

Serengeti wildebeest migratory patterns modeled from rainfall and new vegetation growth

Abstract

Keywords

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Datasets

Appendix B. Locations on the 15th of each month of wildebeest simulated in the evolutionary stage for models influenced by rainfall and new vegetation growth, as reflected in NDVI.

Appendix A. Measures of goodness-of-fit for wildebeest pathways from eight objective functions averaged for multiple-resolution comparisons from 5 to 50 km square blocks.

Appendix C. Nine wildebeest migratory pathways that evolved using average monthly surfaces in the additive model and yearly pathways refined in a learning phase.

Cite this