Certifying Euclidean Sections and Finding Planted Sparse Vectors Beyond the n Dimension Threshold

Abstract

We consider the task of certifying that a random d-dimensional subspace X in Rn is well-spread - every vector x ∈ X satisfies cn \|x\|2 ≤ \|x\|1 ≤ n\|x\|2. In a seminal work, Barak et. al. showed a polynomial-time certification algorithm when d ≤ O(n). On the other hand, when d n, the certification task is information-theoretically possible but there is evidence that it is computationally hard [MW21,Cd22], a phenomenon known as the information-computation gap. In this paper, we give subexponential-time certification algorithms in the d n regime. Our algorithm runs in time (O(n)) when d ≤ O(n(1+)/2), establishing a smooth trade-off between runtime and the dimension. Our techniques naturally extend to the related planted problem, where the task is to recover a sparse vector planted in a random subspace. Our algorithm achieves the same runtime and dimension trade-off for this task.

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