Testing Matrix Rank, Optimally

Balcan, Maria-Florina; Li, Yang; Woodruff, David P.; Zhang, Hongyang

doi:10.1137/1.9781611975482.46

Cited by 13 publications

(18 citation statements)

References 41 publications

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“…In this noiseless problem, one aims at recovering functionals of A such as a Schatten norm or the rank using the smallest possible budget. See [2,19,26]. As in our noisy framework, [26] emphasizes that estimating even Schatten norms using sketches seems easier than estimating non-even Schatten norms.…”

Section: Related Literaturementioning

confidence: 99%

“…Most work around effective ranks consider noiseless setting [33], but the matrix A is sometimes allowed to be only partially observed (e.g [2]). In this work, we tackle the general problem of estimating the effective rank of A relying on a single noisy observation Y of A.…”

Section: Effective Rank Of a Matrixmentioning

confidence: 99%

“…The latter problem is classicalsee e.g. [9] and our simple estimator U 1 for A 2 2 has been already analyzed in the Gaussian sequence model. Still, we provide here a self-contained analysis as a warming-up for general even Schatten norms.…”

Section: Frobenius Normsmentioning

confidence: 99%

“…Still, we provide here a self-contained analysis as a warming-up for general even Schatten norms. Since Y 2 2 follows a non-central χ 2 distribution, we derive from standard computations for the normal random variables that E[ Y 2 2 ] = A 2 2 + pq. This leads us to the following unbiased estimator…”

Section: Frobenius Normsmentioning

confidence: 99%

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Optimal Estimation of Schatten Norms of a rectangular Matrix

Thépaut¹,

Verzélen²

2021

Preprint

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We consider the twin problems of estimating the effective rank and the Schatten norms A s of a rectangular p × q matrix A from noisy observations. When s is an even integer, we introduce a polynomial-time estimator of A s that achieves the minimax rate (pq) 1/4 . Interestingly, this optimal rate does not depend on the underlying rank of the matrix A. When s is not an even integer, the optimal rate is much slower. A simple thresholding estimator of the singular values achieves the rate (q ∧ p)(pq) 1/4 , which turns out to be optimal up to a logarithmic multiplicative term. The tight minimax rate is achieved by a more involved polynomial approximation method. This allows us to build estimators for a class of effective rank indices. As a byproduct, we also characterize the minimax rate for estimating the sequence of singular values of a matrix.

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Section: Related Literaturementioning

confidence: 99%

Section: Effective Rank Of a Matrixmentioning

confidence: 99%

Section: Frobenius Normsmentioning

confidence: 99%

Section: Frobenius Normsmentioning

confidence: 99%

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Optimal Estimation of Schatten Norms of a rectangular Matrix

Thépaut¹,

Verzélen²

2021

Preprint

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“…We note that for non-adaptive queries, there is an Ω(n 2 ) sketching lower bound over the reals given in [19], and an Ω(n 2 / log p) lower bound for finite fields (of size p) in [3]. There is also a property testing lower bound in [6], though such a lower bound makes additional assumptions on the input. Thus, our model gives a new lens to study this problem from, from which we are able to derive strong lower bounds for adaptive queries.…”

Section: Introductionmentioning

confidence: 99%

Querying a Matrix through Matrix-Vector Products

Sun

Woodruff

Yang

et al. 2021

ACM Trans. Algorithms

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We consider algorithms with access to an unknown matrix M ε F n×d via matrix-vector products , namely, the algorithm chooses vectors v 1 , ⃛ , v q , and observes Mv 1 , ⃛ , Mv q . Here the v i can be randomized as well as chosen adaptively as a function of Mv 1 , ⃛ , Mv i-1 . Motivated by applications of sketching in distributed computation, linear algebra, and streaming models, as well as connections to areas such as communication complexity and property testing, we initiate the study of the number q of queries needed to solve various fundamental problems. We study problems in three broad categories, including linear algebra, statistics problems, and graph problems. For example, we consider the number of queries required to approximate the rank, trace, maximum eigenvalue, and norms of a matrix M; to compute the AND/OR/Parity of each column or row of M, to decide whether there are identical columns or rows in M or whether M is symmetric, diagonal, or unitary; or to compute whether a graph defined by M is connected or triangle-free. We also show separations for algorithms that are allowed to obtain matrix-vector products only by querying vectors on the right, versus algorithms that can query vectors on both the left and the right. We also show separations depending on the underlying field the matrix-vector product occurs in. For graph problems, we show separations depending on the form of the matrix (bipartite adjacency versus signed edge-vertex incidence matrix) to represent the graph. Surprisingly, very few works discuss this fundamental model, and we believe a thorough investigation of problems in this model would be beneficial to a number of different application areas.

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