Difference between revisions of "Negative Binomial Regression"
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− | Negative binomial regression is appropriate when variance >> mean. A variation of this method, called zero-inflation correction, allows one to control for excess zeros. | + | Negative binomial regression is appropriate when variance >> mean. A variation of this method, called zero-inflation correction, allows one to control for excess zeros. Zero-inflation binomial regression allows one, in a single regression, to select variables that contribute to the true content in the response variable (“count model coefficients”) and also a (potentially |
different) set of variables that contribute to the excess zeros in the response (“zero-inflation model coefficients”). | different) set of variables that contribute to the excess zeros in the response (“zero-inflation model coefficients”). | ||
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+ | == Relevant Papers == | ||
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+ | {{#ask: [[UsesMethod::Negative Binomial Regression]] | ||
+ | | ?AddressesProblem | ||
+ | | ?UsesDataset | ||
+ | }} |
Latest revision as of 22:22, 31 March 2011
This is a regression method that is preferable in certain situations to Poisson Regression.
Typically, Poisson regression is used to model counts of various kinds. However, Poisson random variables are expected to have a mean equal to its variance, which is often not the case in real-world situations. An example of this is the maximum diffusion length of Facebook fan pages in Sun, E., I. Rosenn, C. A Marlow, and T. M Lento. Gesundheit! Modeling Contagion through Facebook News Feed. Proc. ICWSM 9.
Formally, a Poisson distribution can be characterized as:
Whereas the negative binomial distribution can be defined as:
Negative binomial regression is appropriate when variance >> mean. A variation of this method, called zero-inflation correction, allows one to control for excess zeros. Zero-inflation binomial regression allows one, in a single regression, to select variables that contribute to the true content in the response variable (“count model coefficients”) and also a (potentially different) set of variables that contribute to the excess zeros in the response (“zero-inflation model coefficients”).