Family-wise Error Rate Control with E-values

The closure principle is a standard tool for achieving family-wise error rate (FWER) control in multiple testing problems. In general, the computational cost for closed testing can be exponential in the number of hypotheses. The celebrated graphical approach of FWER control overcomes the computational hurdle by using weighted Bonferroni local tests on p-values with appropriately chosen weights. In this study, we extend the graphical approach to e-values. With valid e-values -- common in settings of sequential hypothesis testing or universal inference for irregular parametric models -- we can derive strictly more powerful local tests based on weighted averages of e-values. Consequently, this e-value-based closed test is more powerful than the corresponding graphical approach with inverse e-values as p-values. Although the computational shortcuts for the p-value-based graphical approach are not applicable, we develop efficient polynomial-time algorithms using dynamic programming for e-value-based graphical approaches with any directed acyclic graph. For special graphs, such as those used in the Holm's procedure and fallback procedure, we develop tailored algorithms with computation cost linear in the number of hypotheses, up to logarithmic factors.