Your search keyword '"predictive maps"' showing total 3 results

1. Ecological niche modeling of potential West Nile virus vector mosquito species in Iowa.

Author

Larson, Scott R., DeGroote, John P., Bartholomay, Lyric C., and Sugumaran, Ramanathan

Subjects

*WEST Nile virus, *MOSQUITO vectors, *ECOLOGICAL niche, *MAXIMUM entropy method

Abstract

The article discusses a study concerning the modeling of ecological niche of three West Nile virus (WNV) vector mosquito species in Iowa. It is stated that three niche models were developed by using Ecological niche modeling (ENM) algorithms, Maximum Entropy Species Distribution Modeling (Maxent) and Genetic Algorithm for Rule-set Prediction (GARP). It further states that niche models created by the Maxent were the most useful indicator of WNV human incidence in Iowa.

Published

2010

2. A comparative evaluation of presence-only methods for modelling species distribution.

Author

Tsoar, Asaf, Allouche, Omri, Steinitz, Ofer, Rotem, Dotan, and Kadmon, Ronen

Subjects

*ECOLOGY, *HABITATS, *SPECIES, *BIOLOGICAL classification, *SPECIES distribution, *WILDLIFE conservation, *PLANT species pools, *SPECIES pools, *WILDLIFE recovery

Abstract

In spite of increasing application of presence-only models in ecology and conservation and the growing number of such models, little is known about the relative performance of different modelling methods, and some of the leading models (e.g. GARP and ENFA) have never been compared with one another. Here we compare the performance of six presence-only models that have been selected to represent an increasing level of model complexity [BIOCLIM, HABITAT, Mahalanobis distance (MD), DOMAIN, ENFA, and GARP] using data on the distribution of 42 species of land snails, nesting birds, and insectivorous bats in Israel. The models were calibrated using data from museum collections and observation databases, and their predictions were evaluated using Cohen's Kappa based on field data collected in a standardized sampling design covering most parts of Israel. Predictive accuracy varied between modelling methods with GARP and MD showing the highest accuracy, BIOCLIM and ENFA showing the lowest accuracy, and HABITAT and DOMAIN showing intermediate accuracy levels. Yet, differences between the various models were relatively small except for GARP and MD that were significantly more accurate than BIOCLIM and ENFA. In spite of large differences among species in prevalence and niche width, neither prevalence nor niche width interacted with the modelling method in determining predictive accuracy. However, species with relatively narrow niches were modelled more accurately than species with wider niches. Differences among species in predictive accuracy were highly consistent over all modelling methods, indicating the need for a better understanding of the ecological and geographical factors that influence the performance of species distribution models. [ABSTRACT FROM AUTHOR]

Published

2007

3. Ecological Niche Modeling of Potential West Nile Virus Vector Mosquito Species in Iowa

Author

Ramanathan Sugumaran, Lyric C. Bartholomay, Scott R. Larson, and John DeGroote

Subjects

Culex, predictive maps, Species distribution, Culex tarsalis, Models, Biological, Arbovirus, Article, Aedes vexans, GARP, Aedes, Culex pipiens, medicine, Animals, Humans, Ecosystem, Ecological niche, biology, Ecology, Incidence, General Medicine, medicine.disease, biology.organism_classification, Iowa, Insect Vectors, Environmental niche modelling, Insect Science, Maxent, Algorithms, West Nile Fever

Abstract

Ecological niche modeling (ENM) algorithms, Maximum Entropy Species Distribution Modeling (Maxent) and Genetic Algorithm for Rule-set Prediction (GARP), were used to develop models in Iowa for three species of mosquito - two significant, extant West Nile virus (WNV) vectors (Culex pipiens L and Culex tarsalis Coquillett (Diptera: Culicidae)), and the nuisance mosquito, Aedes vexans Meigen (Diptera: Culicidae), a potential WNV bridge vector. Occurrence data for the three mosquito species from a state-wide arbovirus surveillance program were used in combination with climatic and landscape layers. Maxent successfully created more appropriate niche models with greater accuracy than GARP. The three Maxent species' models were combined and the average values were statistically compared to human WNV incidence at the census block group level. The results showed that the Maxent-modeled species' niches averaged together were a useful indicator of WNV human incidence in the state of Iowa. This simple method for creating probability distribution maps proved useful for understanding WNV dynamics and could be applied to the study of other vector-borne diseases.

Published

2010