The MI Procedure |
Propensity Score Method for Monotone Missing Data |
The propensity score method is another imputation method available for continuous variables when the data set has a monotone missing pattern.
A propensity score is generally defined as the conditional probability of assignment to a particular treatment given a vector of observed covariates (Rosenbaum and Rubin 1983). In the propensity score method, for a variable with missing values, a propensity score is generated for each observation to estimate the probability that the observation is missing. The observations are then grouped based on these propensity scores, and an approximate Bayesian bootstrap imputation (Rubin 1987, p. 124) is applied to each group (Lavori, Dawson, and Shera 1995).
The propensity score method uses the following steps to impute values for variable with missing values:
Create an indicator variable with the value 0 for observations with missing and 1 otherwise.
Fit a logistic regression model
where are covariates for , , and
Create a propensity score for each observation to estimate the probability that it is missing.
Divide the observations into a fixed number of groups (typically assumed to be five) based on these propensity scores.
Apply an approximate Bayesian bootstrap imputation to each group. In group , suppose that denotes the observations with nonmissing values and denotes the observations with missing . The approximate Bayesian bootstrap imputation first draws observations randomly with replacement from to create a new data set . This is a nonparametric analog of drawing parameters from the posterior predictive distribution of the parameters. The process then draws the values for randomly with replacement from .
Steps 1 through 5 are repeated sequentially for each variable with missing values.
Note that the propensity score method was originally designed for a randomized experiment with repeated measures on the response variables. The goal was to impute the missing values on the response variables. The method uses only the covariate information that is associated with whether the imputed variable values are missing. It does not use correlations among variables. It is effective for inferences about the distributions of individual imputed variables, such as a univariate analysis, but it is not appropriate for analyses involving relationship among variables, such as a regression analysis (Schafer 1999, p. 11). It can also produce badly biased estimates of regression coefficients when data on predictor variables are missing (Allison 2000).
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