A Computational Transition for Detecting Multivariate Shuffled Linear Regression by Low-Degree Polynomials
Abstract
In this paper, we study the problem of multivariate shuffled linear regression, where the correspondence between predictors and responses in a linear model is obfuscated by a latent permutation. Specifically, we investigate the model Y=11+σ2(* X Q* + σ Z), where X is an n*d standard Gaussian design matrix, Z is an n*m Gaussian noise matrix, * is an unknown n*n permutation matrix, and Q* is an unknown d*m on the Grassmanian manifold satisfying Q* Q* = Im. Consider the hypothesis testing problem of distinguishing this model from the case where X and Y are independent Gaussian random matrices of sizes n*d and n*m, respectively. Our results reveal a phase transition phenomenon in the performance of low-degree polynomial algorithms for this task. (1) When m=o(d), we show that all degree-D polynomials fail to distinguish these two models even when σ=0, provided with D4=o( dm ). (2) When m=d and σ=ω(1), we show that all degree-D polynomials fail to distinguish these two models provided with D=o(σ). (3) When m=d and σ=o(1), we show that there exists a constant-degree polynomial that strongly distinguish these two models. These results establish a smooth transition in the effectiveness of low-degree polynomial algorithms for this problem, highlighting the interplay between the dimensions m and d, the noise level σ, and the computational complexity of the testing task.
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