Spectral Properties of Elementwise-Transformed Spiked Matrices
Abstract
This work concerns elementwise-transformations of spiked matrices: Yn = n-1/2 f( n Xn + Zn). Here, f is a function applied elementwise, Xn is a low-rank signal matrix, and Zn is white noise. We find that principal component analysis is powerful for recovering signal under highly nonlinear or discontinuous transformations. Specifically, in the high-dimensional setting where Yn is of size n × p with n,p → ∞ and p/n → γ > 0, we uncover a phase transition: for signal-to-noise ratios above a sharp threshold -- depending on f, the distribution of elements of Zn, and the limiting aspect ratio γ -- the principal components of Yn (partially) recover those of Xn. Below this threshold, the principal components of Yn are asymptotically orthogonal to the signal. In contrast, in the standard setting where Xn + n-1/2Zn is observed directly, the analogous phase transition depends only on γ. A similar phenomenon occurs with Xn square and symmetric and Zn a generalized Wigner matrix.
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