Spiked Covariance Estimation from Modulo-Reduced Measurements
Abstract
Consider the rank-1 spiked model: X= u+ Z, where is the spike intensity, u∈Sk-1 is an unknown direction and N(0,1),Z N(0,I). Motivated by recent advances in analog-to-digital conversion, we study the problem of recovering u∈ Sk-1 from n i.i.d. modulo-reduced measurements Y=[X] , focusing on the high-dimensional regime (k 1). We develop and analyze an algorithm that, for most directions u and =poly(k), estimates u to high accuracy using n=poly(k) measurements, provided that k. Up to constants, our algorithm accurately estimates u at the smallest possible that allows (in an information-theoretic sense) to recover X from Y. A key step in our analysis involves estimating the probability that a line segment of length ≈ in a random direction u passes near a point in the lattice Zk. Numerical experiments show that the developed algorithm performs well even in a non-asymptotic setting.
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