Cross-fitting in causal machine learning with correlated units

Salvador Balkus Speaker
Harvard T.H. Chan School of Public Health
 
Hasan Laith Co-Author
Harvard College
 
Nima Hejazi Co-Author
Harvard T.H. Chan School of Public Health
 
Monday, Aug 3: 10:35 AM - 10:50 AM
1925 
Contributed Papers 
Thomas M. Menino Convention & Exhibition Center 
In causal machine learning, the fitting and evaluation of nuisance models are typically performed on separate partitions, or folds, of the observed data. This technique, called cross-fitting, eliminates bias introduced by the use of black-box predictive algorithms. When study units may be correlated, such as in spatial, clustered, or time-series data, investigators often design bespoke forms of cross-fitting to minimize correlation between folds. We prove that, perhaps contrary to popular belief, this is typically unnecessary: performing cross-fitting as if study units were independent usually still eliminates key bias terms even when units may be correlated. In simulation experiments with various correlation structures, we show that causal machine learning estimators typically have the same or improved bias and precision under cross-fitting that ignores correlation compared to techniques striving to eliminate correlation between folds.

Keywords

cross-fitting

causal machine learning

correlated data

spatial data

clustered data

semi-parametric estimation 

Main Sponsor

Section on Statistical Learning and Data Science