Model-Free Multiple Testing for Matrix-Valued Predictors with False Discovery Control
提出一种无需模型假设的方法,在高维矩阵数据中同时选择重要行和列,并控制错误发现率,通过数据拆分和镜像统计量实现,理论证明其渐近有效性。
Identifying influential variables in high-dimensional matrix-valued data while controlling the false discovery rate (FDR) is a critical challenge in modern data science. We propose a novel, model-free procedure specifically designed for simultaneous row and column selection in matrix predictor regression. Our approach utilizes folding selection subspaces (FSS) to formulate structured hypotheses and employs data splitting to construct mirror statistics from FSS estimators. This design bypasses restrictive model specification and the need for p-value computation. Key theoretical contributions include establishing the asymptotic distribution of FSS estimators and proving the mirror statistic is asymptotically symmetric with respect to zero under the null hypothesis. Using the symmetry, we develop a multiple hypothesis testing procedure with data-driven thresholds that provably controls the FDR for row and column at the desired level asymptotically. The framework is further extended to control element-wise FDR under specific structural assumptions. Extensive simulations and a real data analysis demonstrate the superior performance of the proposed method over existing approaches across various settings.