Unlabeled sensing: Reconstruction algorithm and theoretical guarantees

Elhami, Golnoosh; Scholefield, Adam; Haro, Benjamín Béjar; Vetterli, Martin

doi:10.1109/icassp.2017.7953021

Cited by 20 publications

(12 citation statements)

References 13 publications

(18 reference statements)

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“…A more efficient algorithm is that of [8], which is able to reduce the complexity as a function of m to a factor of at least m 7 . However, as the authors of [8] write, their algorithm strongly exploits the assumption of noiseless measurements and is also very brittle and very likely fails in the presence of noise; the same is true for the O(m n ) complexity algorithm of [38]. Finally, the authors in [8] write we are not aware of previous algorithms for the average-case problem in general dimension n. In the same paper a (1 + ǫ) approximation algorithm with theoretical guarantees and of complexity O((m/ǫ) n ) is proposed, which however, is not meant for practical deployment, but instead is 2.…”

Section: Prior Artmentioning

confidence: 99%

An Algebraic-Geometric Approach for Linear Regression Without Correspondences

Tsakiris

Peng

Conca

et al. 2020

IEEE Trans. Inform. Theory

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Linear regression without correspondences is the problem of performing a linear regression fit to a dataset for which the correspondences between the independent samples and the observations are unknown. Such a problem naturally arises in diverse domains such as computer vision, data mining, communications and biology. In its simplest form, it is tantamount to solving a linear system of equations, for which the entries of the right hand side vector have been permuted. This type of data corruption renders the linear regression task considerably harder, even in the absence of other corruptions, such as noise, outliers or missing entries. Existing methods are either applicable only to noiseless data or they are very sensitive to initialization or they work only for partially shuffled data. In this paper we address these issues via an algebraic geometric approach, which uses symmetric polynomials to extract permutation-invariant constraints that the parameters ξ * ∈ R n of the linear regression model must satisfy. This naturally leads to a polynomial system of n equations in n unknowns, which contains ξ * in its root locus. Using the machinery of algebraic geometry we prove that as long as the independent samples are generic, this polynomial system is always consistent with at most n! complex roots, regardless of any type of corruption inflicted on the observations. The algorithmic implication of this fact is that one can always solve this polynomial system and use its most suitable root as initialization to the Expectation Maximization algorithm. To the best of our knowledge, the resulting method is the first working solution for small values of n able to handle thousands of fully shuffled noisy observations in milliseconds.

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Section: Prior Artmentioning

confidence: 99%

An Algebraic-Geometric Approach for Linear Regression Without Correspondences

Tsakiris

Peng

Conca

et al. 2020

IEEE Trans. Inform. Theory

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show abstract

“…Instead, we are aware of only two relevant algorithms, which nevertheless are suitable under strong structural assumptions on the data. The O(nm n+1 ) method of [25] applies a brute-force solution, which explicitly relies on the data being noiseless and whose theoretical guarantees require a particular exponentially spaced structure on A. On the other hand, [24] attempt to solve min…”

Section: Prior-artmentioning

confidence: 99%

“…Algorithms. Inspired by [24], [25] and [26] we make three algorithmic contributions. First, we introduce a branch-and-bound algorithm for the unlabeled sensing problem by globally minimizing (3).…”

Section: Contributionsmentioning

confidence: 99%

“…Instead of branching over the space of selection matrices, which is known to be intractable [27], our algorithm only branches over the space of x ∈ R n , relying on a locally optimal computation of the selection matrix via dynamic programming. Second, it is this dynamic programming feature that also allows us to modify the purely theoretical algorithm of [25] into a robust and efficient method for small dimensions n. These two algorithms constitute to the best of our knowledge the first working solutions for the unlabeled sensing problem. Third, when customized for image registration under an affine transformation, our branch-andbound algorithm is on par with or outperforms state-of-the-art methods [10], [28], [29] on benchmark datasets.…”

Section: Contributionsmentioning

confidence: 99%

“…It turns out that the dynamic programming trick of §3.1 is also the key to a robust version of the theoretical algorithm of [25]: we randomly select a sub-vector ȳ of y of length n, and for each A i out of the m!/(m − n)! many n × n matrices that can be made by concatenating different rows of A in any order we let…”

Section: A Robust Version Of [25]mentioning

confidence: 99%

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Homomorphic Sensing

Tsakiris,

Peng

2019

Preprint

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A recent line of research termed unlabeled sensing and shuffled linear regression has been exploring under great generality the recovery of signals from subsampled and permuted measurements; a challenging problem in diverse fields of data science and machine learning. In this paper we introduce an abstraction of this problem which we call homomorphic sensing. Given a linear subspace and a finite set of linear transformations we develop an algebraic theory which establishes conditions guaranteeing that points in the subspace are uniquely determined from their homomorphic image under some transformation in the set. As a special case, we recover known conditions for unlabeled sensing, as well as new results and extensions. On the algorithmic level we exhibit two dynamic programming based algorithms, which to the best of our knowledge are the first working solutions for the unlabeled sensing problem for small dimensions. One of them, additionally based on branch-and-bound, when applied to image registration under affine transformations, performs on par with or outperforms state-of-the-art methods on benchmark datasets.

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Shuffled Linear Regression with Outliers in Both Covariates and Responses

Fujiwara

Okura

et al. 2022

Int J Comput Vis

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Unlabeled sensing: Reconstruction algorithm and theoretical guarantees

Cited by 20 publications

References 13 publications

An Algebraic-Geometric Approach for Linear Regression Without Correspondences

An Algebraic-Geometric Approach for Linear Regression Without Correspondences

Homomorphic Sensing

Shuffled Linear Regression with Outliers in Both Covariates and Responses

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