The goal of etwfe is to estimate extended two-way fixed effects a la Wooldridge (2021, 2023). Briefly, Wooldridge proposes a set of saturated interaction effects to overcome the potential bias problems of vanilla TWFE in difference-in-differences designs. The Wooldridge solution is intuitive and elegant, but rather tedious and error prone to code up manually. The etwfe package aims to simplify the process by providing convenience functions that do the work for you.
Documentation is available on the package homepage.
You can install etwfe from CRAN.
install.packages("etwfe")Or, you can grab the development version from R-universe.
install.packages("etwfe", repos = "https://grantmcdermott.r-universe.dev")A detailed walkthrough of etwfe is provided in the
introductory vignette (available online,
or by typing vignette("etwfe") in your R console). But
here’s a quickstart example to demonstrate the basic syntax.
Start by loading the package and some data.
library(etwfe)
# install.packages("did")
data("mpdta", package = "did")
head(mpdta, 2)
#> year countyreal lpop lemp first.treat treat
#> 866 2003 8001 5.896761 8.461469 2007 1
#> 841 2004 8001 5.896761 8.336870 2007 1Step 1: Run etwfe() to estimate a model
with full saturated interactions.
mod = etwfe(
fml = lemp ~ lpop, # outcome ~ controls
tvar = year, # time variable
gvar = first.treat, # group variable
data = mpdta, # dataset
vcov = ~countyreal # vcov adjustment (here: clustered)
)
mod
#> OLS estimation, Dep. Var.: lemp
#> Observations: 2,500
#> Fixed-effects: first.treat: 4, year: 5
#> Varying slopes: lpop (first.treat): 4, lpop (year): 5
#> Standard-errors: Clustered (countyreal)
#> Estimate Std. Error t value Pr(>|t|)
#> .Dtreat:first.treat::2004:year::2004 -0.021248 0.021728 -0.977890 3.2860e-01
#> .Dtreat:first.treat::2004:year::2005 -0.081850 0.027375 -2.989963 2.9279e-03 **
#> .Dtreat:first.treat::2004:year::2006 -0.137870 0.030795 -4.477097 9.3851e-06 ***
#> .Dtreat:first.treat::2004:year::2007 -0.109539 0.032322 -3.389024 7.5694e-04 ***
#> .Dtreat:first.treat::2006:year::2006 0.002537 0.018883 0.134344 8.9318e-01
#> .Dtreat:first.treat::2006:year::2007 -0.045093 0.021987 -2.050907 4.0798e-02 *
#> .Dtreat:first.treat::2007:year::2007 -0.045955 0.017975 -2.556568 1.0866e-02 *
#> .Dtreat:first.treat::2004:year::2004:lpop_dm 0.004628 0.017584 0.263184 7.9252e-01
#> .Dtreat:first.treat::2004:year::2005:lpop_dm 0.025113 0.017904 1.402661 1.6134e-01
#> .Dtreat:first.treat::2004:year::2006:lpop_dm 0.050735 0.021070 2.407884 1.6407e-02 *
#> .Dtreat:first.treat::2004:year::2007:lpop_dm 0.011250 0.026617 0.422648 6.7273e-01
#> .Dtreat:first.treat::2006:year::2006:lpop_dm 0.038935 0.016472 2.363731 1.8474e-02 *
#> .Dtreat:first.treat::2006:year::2007:lpop_dm 0.038060 0.022477 1.693276 9.1027e-02 .
#> .Dtreat:first.treat::2007:year::2007:lpop_dm -0.019835 0.016198 -1.224528 2.2133e-01
#> ... 10 variables were removed because of collinearity (.Dtreat:first.treat::2006:year::2004, .Dtreat:first.treat::2006:year::2005 and 8 others [full set in $collin.var])
#> ---
#> Signif. codes: 0 '***' 0.001 '**' 0.01 '*' 0.05 '.' 0.1 ' ' 1
#> RMSE: 0.537131 Adj. R2: 0.87167
#> Within R2: 8.449e-4Step 2: Pass to emfx() to recover the
ATTs of interest. In this case, an event-study example.
emfx(mod, type = "event")
#>
#> Term event Estimate Std. Error z Pr(>|z|) S 2.5 % 97.5 %
#> .Dtreat 0 -0.0332 0.0134 -2.48 0.013 6.3 -0.0594 -0.00701
#> .Dtreat 1 -0.0573 0.0172 -3.34 <0.001 10.2 -0.0910 -0.02373
#> .Dtreat 2 -0.1379 0.0308 -4.48 <0.001 17.0 -0.1982 -0.07751
#> .Dtreat 3 -0.1095 0.0323 -3.39 <0.001 10.5 -0.1729 -0.04619
#>
#> Type: response
#> Comparison: TRUE - FALSE
#> Columns: term, contrast, event, estimate, std.error, statistic, p.value, s.value, conf.low, conf.highjwdid
Stata module, which has provided a welcome foil for unit testing and
whose elegant design helped inform my own choices for this R
equivalent.