--- title: "Non-binary Treatment Specification" date: "`r Sys.Date()`" output: rmarkdown::html_vignette vignette: > %\VignetteIndexEntry{Non-binary Treatment Specification} %\VignetteEngine{knitr::rmarkdown} %\VignetteEncoding{UTF-8} --- ```{r setup, include = FALSE} knitr::opts_chunk$set( collapse = TRUE, comment = "#>" ) library(propertee) ``` ## Binary Treatment When creating a StudySpecification, handling binary treatment variables is straightforward. If the treatment variable is either `numeric` with only values 0/1, or is `logical`, then `lmitt()` will estimate a treatment effect of the difference between the outcome in the treated group (`1` or `TRUE`) versus the control group (`0` or `FALSE`). ### Missing treatment status In all cases (binary and non-binary), missing values are allowed and any units of assignment with missing treatment values are excluded from models fit via `lmitt()`. ## Non-binary Treatment However, the [`_spec()`](../reference/StudySpecification_objects.html) functions can take in any (reasonable) form of treatment assignment. If the treatment variable is a `numeric` with non-binary values, it is treated as a continuous treatment effect and `lmitt(y ~ 1, ...` will estimate a single coefficient on treatment. If the treatment variable is a `character`, it is treated as a multi-level treatment variable and `lmitt(y ~ 1, ...` will estimate treatment effects against a reference category. The reference category is the first level defined according to [R's comparison of characters](https://rdrr.io/r/base/Comparison.html). `factor` and `ordered` objects are tricky to deal with, so while a `StudySpecification` can be created with `factor` or `ordered` treatment variables, `lmitt()` will refuse to estimate a model unless it is also provided a [`dichotomy`](#dichotomzing-a-non-binary-treatment) (see below). ### Dichotomzing a Non-binary Treatment Studies may offer treatment to units at different times or provide treatment to units in varying intensities. Researchers may be interested in estimating treatment effects at different times or given a certain threshold of provided treatment, however. `propertee` accommodates these wishes by storing the time or intensity of treatment for treated units in the [`StudySpecification`](../reference/StudySpecification_objects.html), then offering a `dichotomy=` argument to the weights calculation functions `ett()`/`ate()` and the assginment creation function `assigned()` A `dichotomy` is presented as a formula, where the left-hand side is a logical statement defining inclusion in the treatment group, and the right-hand side is a logical statement defining inclusion in the control group. For example, if `dose` represents the intensity of a given treatment, we could set a threshold of 200, say, mg: ```{r, eval = FALSE} dose > 200 ~ dose <= 200 ``` All units of assignment with `dose` above 200 are treated units, and all units of assignment with `dose` of 200 or below are control units. A `.` can be used to define either group as the inverse of the other. For example, the above dichotomy could be defined as either of ```{r, eval = FALSE} dose > 200 ~ . . ~ dose <= 200 ``` Any units of assignment not assigned to either treatment or control are assumed to have `NA` for a treatment status and will be ignored in the estimation of treatment effects. ```{r, eval = FALSE} dose >= 300 ~ dose <= 100 ``` In this `dichotomy`, units of assignment in the range (100,300) are ignored. ### An Example ```{r} data(simdata) table(simdata$dose) spec1 <- rct_spec(dose ~ uoa(uoa1, uoa2), data = simdata) summary(spec1) ``` ```{r} head(ate(spec1, data = simdata, dichotomy = dose >= 300 ~ dose <= 100)) ``` ```{r} head(assigned(spec1, data = simdata, dichotomy = dose >= 300 ~ dose <= 100)) ```