A Bayesian geostatistical Moran Curve model for estimating net changes of tsetse populations in Zambia
A Bayesian geostatistical Moran Curve model for estimating net changes of tsetse populations in Zambia
For the first time a Bayesian geostatistical version of the Moran Curve, a logarithmic form of the Ricker stock recruitment curve, is proposed that is able to give an estimate of net change in population demographic rates considering components such as fertility and density dependent and density independent mortalities. The method is applied to spatio-temporally referenced count data of tsetse flies obtained from fly-rounds. The model is a linear regression with three components: population rate of change estimated from the Moran curve, an explicit spatio-temporal covariance, and the observation error optimised within a Bayesian framework. The model was applied to the three main climate seasons of Zambia (rainy – January to April, cold-dry – May to August, and hot-dry – September to December) taking into account land surface temperature and (seasonally changing) cattle distribution. The model shows a maximum positive net change during the hot-dry season and a minimum between the rainy and cold-dry seasons. Density independent losses are correlated positively with day-time land surface temperature and negatively with night-time land surface temperature and cattle distribution. The inclusion of density dependent mortality increases considerably the goodness of fit of the model. Cross validation with an independent dataset taken from the same area resulted in a very accurate estimate of tsetse catches. In general, the overall framework provides an important tool for vector control and eradication by identifying vector population concentrations and local vector demographic rates. It can also be applied to the case of sustainable harvesting of natural populations
e96002
Sedda, L.
ae6a74e0-ff67-4678-aefc-9976179294f6
Mweempwa, C.
b64e1f01-af94-43a6-98af-89b64d38270b
Ducheyne, E.
8c46d44b-c40c-4f4b-84ee-6b8309e18d24
De Pus, C.
56c081f5-625b-4fb3-b12d-900b8390063b
Hendrickx, G.
04235457-0052-48aa-93dd-49e925601759
Rogers, D.J.
90d6a7d6-f68c-4056-8ac9-3f52ced25f30
22 April 2014
Sedda, L.
ae6a74e0-ff67-4678-aefc-9976179294f6
Mweempwa, C.
b64e1f01-af94-43a6-98af-89b64d38270b
Ducheyne, E.
8c46d44b-c40c-4f4b-84ee-6b8309e18d24
De Pus, C.
56c081f5-625b-4fb3-b12d-900b8390063b
Hendrickx, G.
04235457-0052-48aa-93dd-49e925601759
Rogers, D.J.
90d6a7d6-f68c-4056-8ac9-3f52ced25f30
Sedda, L., Mweempwa, C., Ducheyne, E., De Pus, C., Hendrickx, G. and Rogers, D.J.
(2014)
A Bayesian geostatistical Moran Curve model for estimating net changes of tsetse populations in Zambia.
PLoS ONE, 9 (4), .
(doi:10.1371/journal.pone.0096002).
Abstract
For the first time a Bayesian geostatistical version of the Moran Curve, a logarithmic form of the Ricker stock recruitment curve, is proposed that is able to give an estimate of net change in population demographic rates considering components such as fertility and density dependent and density independent mortalities. The method is applied to spatio-temporally referenced count data of tsetse flies obtained from fly-rounds. The model is a linear regression with three components: population rate of change estimated from the Moran curve, an explicit spatio-temporal covariance, and the observation error optimised within a Bayesian framework. The model was applied to the three main climate seasons of Zambia (rainy – January to April, cold-dry – May to August, and hot-dry – September to December) taking into account land surface temperature and (seasonally changing) cattle distribution. The model shows a maximum positive net change during the hot-dry season and a minimum between the rainy and cold-dry seasons. Density independent losses are correlated positively with day-time land surface temperature and negatively with night-time land surface temperature and cattle distribution. The inclusion of density dependent mortality increases considerably the goodness of fit of the model. Cross validation with an independent dataset taken from the same area resulted in a very accurate estimate of tsetse catches. In general, the overall framework provides an important tool for vector control and eradication by identifying vector population concentrations and local vector demographic rates. It can also be applied to the case of sustainable harvesting of natural populations
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Published date: 22 April 2014
Organisations:
Global Env Change & Earth Observation
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Local EPrints ID: 364350
URI: http://eprints.soton.ac.uk/id/eprint/364350
ISSN: 1932-6203
PURE UUID: d11f8cc7-e1f4-4444-9fa8-41d79f32c32a
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Date deposited: 24 Apr 2014 10:23
Last modified: 14 Mar 2024 16:34
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Author:
L. Sedda
Author:
C. Mweempwa
Author:
E. Ducheyne
Author:
C. De Pus
Author:
G. Hendrickx
Author:
D.J. Rogers
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