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Main Authors: Azriel, David, Krieger, Abba M., Kapelner, Adam
Format: Preprint
Published: 2022
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Online Access:https://arxiv.org/abs/2212.01887
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author Azriel, David
Krieger, Abba M.
Kapelner, Adam
author_facet Azriel, David
Krieger, Abba M.
Kapelner, Adam
contents We consider the performance of the difference-in-means estimator in a two-arm randomized experiment under common experimental endpoints such as continuous (regression), incidence, proportion and survival. We examine performance under both equal and unequal allocation to treatment groups and we consider both the Neyman randomization model and the population model. We show that in the Neyman model, where the only source of randomness is the treatment manipulation, there is no free lunch: complete randomization is minimax for the estimator's mean squared error. In the population model, where each subject experiences response noise with zero mean, the optimal design is the deterministic perfect-balance allocation. However, this allocation is generally NP-hard to compute and moreover, depends on unknown response parameters. When considering the tail criterion of Kapelner et al. (2021), we show the optimal design is less random than complete randomization and more random than the deterministic perfect-balance allocation. We prove that Fisher's blocking design provides the asymptotically optimal degree of experimental randomness. Theoretical results are supported by simulations in all considered experimental settings.
format Preprint
id arxiv_https___arxiv_org_abs_2212_01887
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle The Optimality of Blocking Designs in Equally and Unequally Allocated Randomized Experiments with General Response
Azriel, David
Krieger, Abba M.
Kapelner, Adam
Statistics Theory
Methodology
We consider the performance of the difference-in-means estimator in a two-arm randomized experiment under common experimental endpoints such as continuous (regression), incidence, proportion and survival. We examine performance under both equal and unequal allocation to treatment groups and we consider both the Neyman randomization model and the population model. We show that in the Neyman model, where the only source of randomness is the treatment manipulation, there is no free lunch: complete randomization is minimax for the estimator's mean squared error. In the population model, where each subject experiences response noise with zero mean, the optimal design is the deterministic perfect-balance allocation. However, this allocation is generally NP-hard to compute and moreover, depends on unknown response parameters. When considering the tail criterion of Kapelner et al. (2021), we show the optimal design is less random than complete randomization and more random than the deterministic perfect-balance allocation. We prove that Fisher's blocking design provides the asymptotically optimal degree of experimental randomness. Theoretical results are supported by simulations in all considered experimental settings.
title The Optimality of Blocking Designs in Equally and Unequally Allocated Randomized Experiments with General Response
topic Statistics Theory
Methodology
url https://arxiv.org/abs/2212.01887