Analysis of Multinomial Models With Unknown Index Using Data Augmentation

Multinomial models with unknown index ("sample size") arise in many practical settings. In practice, Bayesian analysis of such models has proved difficult because the dimension of the parameter space is not fixed, being in some cases a function of the unknown index. We describe a data augm...

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Bibliographic Details
Published in:Journal of computational and graphical statistics 2007-03, Vol.16 (1), p.67-85
Main Authors: Royle, J. Andrew, Dorazio, Robert M, Link, William A
Format: Article
Language:English
Subjects:
Animal populations
Bayesian analysis
Capture-recapture
Data analysis
Datasets
Diabetes
Ecological modeling
Mathematical independent variables
Mathematical models
Modeling
Multiple lists
Parameter estimation
Parametric models
Population estimates
Population size
Population size estimation
Rasch model
Site-occupancy
Species
Species richness
Studies
Zero-inflation
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Summary:Multinomial models with unknown index ("sample size") arise in many practical settings. In practice, Bayesian analysis of such models has proved difficult because the dimension of the parameter space is not fixed, being in some cases a function of the unknown index. We describe a data augmentation approach to the analysis of this class of models that provides for a generic and efficient Bayesian implementation. Under this approach, the data are augmented with all-zero detection histories. The resulting augmented dataset is modeled as a zero-inflated version of the complete-data model where an estimable zero-inflation parameter takes the place of the unknown multinomial index. Interestingly, data augmentation can be justified as being equivalent to imposing a discrete uniform prior on the multinomial index. We provide three examples involving estimating the size of an animal population, estimating the number of diabetes cases in a population using the Rasch model, and the motivating example of estimating the number of species in an animal community with latent probabilities of species occurrence and detection.
ISSN:1061-8600
1537-2715
DOI:10.1198/106186007X181425