The main motivation for zero-inflated count models is that real-life data frequently display overdispersion and excess zeros. Zero-inflated count models provide a way of modeling the excess zeros in addition to allowing for overdispersion. In particular, for each observation, there are two possible data generation processes. The result of a Bernoulli trial is used to determine which of the two processes is used. For observation , Process 1 is chosen with probability and Process 2 with probability . Process 1 generates only zero counts. Process 2 generates counts from either a Poisson or a negative binomial model. In general,
Therefore, the probability of can be described as
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where follows either the Poisson or the negative binomial distribution. You can specify the probability with the PROBZERO= option in the OUTPUT statement.
When the probability depends on the characteristics of observation , is written as a function of , where is the vector of zero-inflation covariates and is the vector of zero-inflation coefficients to be estimated. (The zero-inflation intercept is ; the coefficients for the zero-inflation covariates are .) The function that relates the product (which is a scalar) to the probability is called the zero-inflation link function,
In the TCOUNTREG procedure, the zero-inflation covariates are indicated in the ZEROMODEL statement. Furthermore, the zero-inflation link function can be specified as either the logistic function,
or the standard normal cumulative distribution function (also called the probit function),
The zero-inflation link function is indicated in the LINK option in ZEROMODEL statement. The default ZI link function is the logistic function.