The staggered R package computes the efficient estimator for settings with randomized treatment timing, based on the theoretical results in Roth and Sant’Anna (2021). If units are randomly (or quasi-randomly) assigned to begin treatment at different dates, the efficient estimator can potentially offer substantial gains over methods that only impose parallel trends. The package also allows for calculating the generalized difference-in-differences estimators of Callaway and Sant’Anna (2020) and Sun and Abraham (2020) and the simple-difference-in-means as special cases. We also provide a Stata implementation via the RCall package.

You can install the package from GitHub with:

```
# install.packages("devtools")
::install_github("jonathandroth/staggered") devtools
```

We now illustrate how to use the package by re-creating some of the results in the application section of Roth and Sant’Anna (2021). Our data contains a balanced panel of police officers in Chicago who were randomly given a procedural justice training on different dates.

We first load the staggered package as well as some auxiliary packages for modifying and plotting the results.

```
library(staggered) #load the staggered package
library(dplyr) #load dplyr for data manipulation
#>
#> Attaching package: 'dplyr'
#> The following objects are masked from 'package:stats':
#>
#> filter, lag
#> The following objects are masked from 'package:base':
#>
#> intersect, setdiff, setequal, union
library(ggplot2) #load ggplot2 for plotting the results
library(purrr)
<- staggered::pj_officer_level_balanced #load the officer data df
```

We now can call the function calculate_adjusted_estimator_and_se to calculate the efficient estimator. With staggered treatment timing, there are several ways to aggregate treatment effects across cohorts and time periods. The following block of code calculates the simple, calendar-weighted, and cohort-weighted average treatment effects (see Section 2.3 of Roth and Sant’Anna (2021) for more about different aggregation schemes).

```
#Calculate efficient estimator for the simple weighted average
staggered(df = df,
i = "uid",
t = "period",
g = "first_trained",
y = "complaints",
estimand = "simple")
#> estimate se se_neyman
#> 1 -0.001126981 0.002115194 0.002119248
```

```
#Calculate efficient estimator for the cohort weighted average
staggered(df = df,
i = "uid",
t = "period",
g = "first_trained",
y = "complaints",
estimand = "cohort")
#> estimate se se_neyman
#> 1 -0.001084689 0.002261011 0.002264876
```

```
#Calculate efficient estimator for the calendar weighted average
staggered(df = df,
i = "uid",
t = "period",
g = "first_trained",
y = "complaints",
estimand = "calendar")
#> estimate se se_neyman
#> 1 -0.00187198 0.00255863 0.002561472
```

We can also calculate an ``event-study’’ that computes the average-treatment effect at each lag since treatment.

```
#Calculate event-study coefficients for the first 24 months (month 0 is instantaneous effect)
<- staggered(df = df,
eventPlotResults i = "uid",
t = "period",
g = "first_trained",
y = "complaints",
estimand = "eventstudy",
eventTime = 0:23)
%>% head()
eventPlotResults #> estimate se se_neyman eventTime
#> 1 3.083575e-04 0.002645327 0.002650957 0
#> 2 2.591678e-03 0.002614563 0.002621513 1
#> 3 -4.872562e-05 0.002622640 0.002623634 2
#> 4 2.043434e-03 0.002715695 0.002720467 3
#> 5 2.977076e-03 0.002653917 0.002659630 4
#> 6 7.979656e-04 0.002721784 0.002727140 5
```

```
#Create event-study plot from the results of the event-study
%>%
eventPlotResults mutate(ymin_ptwise = estimate + 1.96*se,
ymax_ptwise = estimate - 1.96*se)%>%
ggplot(aes(x=eventTime, y =estimate)) +
geom_pointrange(aes(ymin = ymin_ptwise, ymax = ymax_ptwise))+
geom_hline(yintercept =0) +
xlab("Event Time") + ylab("Estimate") +
ggtitle("Effect of Procedural Justice Training on Officer Complaints")
```

The staggered package also allows you to calculate p-values using
permutation tests, also known as Fisher Randomization Tests. These tests
are based on a studentized statistic, and thus are finite-sample exact
for the null of no treatment effects *and* asymptotically correct
for the null of no average treatment effects.

```
#Calculate efficient estimator for the simple weighted average
#Use Fisher permutation test with 500 permutation draws
staggered(df = df,
i = "uid",
t = "period",
g = "first_trained",
y = "complaints",
estimand = "simple",
compute_fisher = T,
num_fisher_permutations = 500)
#> estimate se se_neyman fisher_pval fisher_pval_se_neyman
#> 1 -0.001126981 0.002115194 0.002119248 0.63 0.632
#> num_fisher_permutations
#> 1 500
```

Our package also allows for the calculation of several other estimators proposed in the literature. For convenience we provide special functions for implementing the estimators proposed by Callaway & Sant’Anna and Sun & Abraham. The syntax is nearly identical to that for the efficient estimator:

```
#Calculate Callaway and Sant'Anna estimator for the simple weighted average
staggered_cs(df = df,
i = "uid",
t = "period",
g = "first_trained",
y = "complaints",
estimand = "simple")
#> estimate se se_neyman
#> 1 -0.005176818 0.003928735 0.003930919
```

```
#Calculate Sun and Abraham estimator for the simple weighted average
staggered_sa(df = df,
i = "uid",
t = "period",
g = "first_trained",
y = "complaints",
estimand = "simple")
#> estimate se se_neyman
#> 1 0.01153851 0.01730161 0.01730234
```

The Callaway and Sant’Anna estimator corresponds with calling the staggered function with beta=1 (and the default use_DiD_A0=1), and the Sun and Abraham estimator corresponds with calling staggered with beta=1 and use_last_treated_only=T. If one is interested in the simple difference-in-means, one can call the staggered function with option beta=0.

Note that the standard errors returned in the se column are based on the design-based approach in Roth & Sant’Anna, and thus will differ somewhat from those returned by the did package. The standard errors in se_neyman should be very similar to those returned by the did package, although not identical in finite samples.

We also provide a Stata implementation (staggered_stata) via the RCall package, which calls the staggered R package from within Stata.

To install the staggered_stata package, the user first needs to install the github and RCall packages. This can be done with the following commands

```
> net install github, from("https://haghish.github.io/github/")
> github install haghish/rcall, version("2.5.0")
```

**Important note:** the staggered_stata package was
built under Rcall version 2.5.0, and the recent release of RCall version
3.0 has created some compatibility issues. We will try our best to fix
these issues, but in the meantime it is best to install version 2.5.0,
as in the command above.

Note that the user must have R installed before installing the RCall package. The latest version of R can be downloaded here. The staggered_stata package can then be installed with

`> github install jonathandroth/staggered_stata`

The three packages can also be installed by downloading the ado files from the package webpages (github, RCall, staggered_stata) directly and pasting them into the user’s ado/personal directory.

The syntax for staggered_stata is very similar to that for the staggered R package. Below are a few illustrative examples, using the same data as above.

```
>use "https://github.com/jonathandroth/staggered_stata/raw/master/pj_officer_level_balanced.dta"
>staggered, y("complaints") g("first_trained") t("period") i("uid") estimand("simple")
>staggered_cs, y("complaints") g("first_trained") t("period") i("uid") estimand("eventstudy") eventTimeStart(-2) eventTimeEnd(2)
>staggered_sa, y("complaints") g("first_trained") t("period") i("uid") estimand("cohort")
```

The staggered, staggered_cs, and staggered_as commands all return a vector of coefficients and covariance matrix in ereturn list, and thus can be used with any post-estimation command in Stata (e.g. coefplot).