Tackling the flip ambiguity in wireless sensor network localization and beyond

Bai, Shuanghua; Qi, Houduo

doi:10.1016/j.dsp.2016.05.006

Cited by 18 publications

(26 citation statements)

References 36 publications

(76 reference statements)

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“…A crucial implication of this result is that the (inexact) block sGS decomposition based multi-block majorized ADMM is equivalent to an inexact majorized proximal ALM. Consequently, we are able to prove the convergence of the whole sequence generated by the former even when the step-length is in the range (0,2).…”

Section: Introductionmentioning

confidence: 85%

On the equivalence of inexact proximal ALM and ADMM for a class of convex composite programming

Chen

Sun

et al. 2019

Math. Program.

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In this paper, we show that for a class of linearly constrained convex composite optimization problems, an (inexact) symmetric Gauss-Seidel based majorized multi-block proximal alternating direction method of multipliers (ADMM) is equivalent to an inexact proximal augmented Lagrangian method (ALM). This equivalence not only provides new perspectives for understanding some ADMM-type algorithms but also supplies meaningful guidelines on implementing them to achieve better computational efficiency. Even for the two-block case, a by-product of this equivalence is the convergence of the whole sequence generated by the classic ADMM with a step-length that exceeds the conventional upper bound of (1 + √ 5)/2, if one part of the objective is linear. This is exactly the problem setting in which the very first convergence analysis of ADMM was conducted by Gabay and Mercier in 1976, but, even under notably stronger assumptions, only the convergence of the primal sequence was known. A collection of illustrative examples are provided to demonstrate the breadth of applications for which our results can be used. Numerical experiments on solving a large number of linear and convex quadratic semidefinite programming problems are conducted to illustrate how the theoretical results established here can lead to improvements on the corresponding practical implementations.

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Section: Introductionmentioning

confidence: 85%

On the equivalence of inexact proximal ALM and ADMM for a class of convex composite programming

Chen

Sun

et al. 2019

Math. Program.

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“…Finally, we note that the KEDM formulation in (12) is a generalization of the static EDM formulation in (4). To see the equivalence, note that static points are modeled by a polynomial of degree zero, P = 0, in which case the Gramian becomes G(t) = G 0 since w 0 (t) = 1.…”

Section: Computing the Kedm From Noisy Incompletementioning

confidence: 99%

“…T He famous distance geometry problem (DGP) [1] asks to reconstruct the geometry of a point set from a subset of interpoint distances. It models a wide gamut of practical problems, from sensor network localization [2], [3], [4] and microphone positioning [5], [6], [7], [8] to clock synchronization [9], [10], to molecular geometry reconstruction from NMR data [11], [12]. Among the most successful vehicles for the design of DGP algorithms are the Euclidean distance matrices (EDM) [13].…”

Section: Introductionmentioning

confidence: 99%

Kinetic Euclidean Distance Matrices

Tabaghi

Vetterli

2020

IEEE Trans. Signal Process.

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Euclidean distance matrices (EDMs) are a major tool for localization from distances, with applications ranging from protein structure determination to global positioning and manifold learning. They are, however, static objects which serve to localize points from a snapshot of distances. If the objects move, one expects to do better by modeling the motion. In this paper, we introduce Kinetic Euclidean Distance Matrices (KEDMs)-a new kind of time-dependent distance matrices that incorporate motion. The entries of KEDMs become functions of time, the squared time-varying distances. We study two smooth trajectory models-polynomial and bandlimited trajectoriesand show that these trajectories can be reconstructed from incomplete, noisy distance observations, scattered over multiple time instants. Our main contribution is a semidefinite relaxation (SDR), inspired by SDRs for static EDMs. Similarly to the static case, the SDR is followed by a spectral factorization step; however, because spectral factorization of polynomial matrices is more challenging than for constant matrices, we propose a new factorization method that uses anchor measurements.Extensive numerical experiments show that KEDMs and the new semidefinite relaxation accurately reconstruct trajectories from noisy, incomplete distance data and that, in fact, motion improves rather than degrades localization if properly modeled. This makes KEDMs a promising tool for problems in geometry of dynamic points sets.

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“…In literature (e.g., [41]), this type of perturbation in δ ij is known to be multiplicative and follows the unit-ball rule in defining N x and N a (see [42,Sect. 3.1] for more detail).…”

Section: A Test Problemsmentioning

confidence: 99%

“…Example 4.2: (EDM word network) This problem has a nonregular topology and is first used in [42] to challenge existing localization methods. In this example, n points are randomly generated in a region whose shape is similar to the letters "E", "D" and "M".…”

Section: A Test Problemsmentioning

confidence: 99%

A Fast Matrix Majorization-Projection Method for Penalized Stress Minimization With Box Constraints

Zhou

Xiu

2018

IEEE Trans. Signal Process.

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Abstract-Kruskal's stress minimization, though nonconvex and nonsmooth, has been a major computational model for dissimilarity data in multidimensional scaling. Semidefinite Programming (SDP) relaxation (by dropping the rank constraint) would lead to a high number of SDP cone constraints. This has rendered the SDP approach computationally challenging even for problems of small size. In this paper, we reformulate the stress optimization as an Euclidean Distance Matrix (EDM) optimization with box constraints. A key element in our approach is the conditional positive semidefinite cone with rank cut. Although nonconvex, this geometric object allows a fast computation of the projection onto it and it naturally leads to a majorization-minimization algorithm with the minimization step having a closed-form solution. Moreover, we prove that our EDM optimization follows a continuously differentiable path, which greatly facilitated the analysis of the convergence to a stationary point. The superior performance of the proposed algorithm is demonstrated against some of the state-of-the-art solvers in the field of sensor network localization and molecular conformation.

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Tackling the flip ambiguity in wireless sensor network localization and beyond

Cited by 18 publications

References 36 publications

On the equivalence of inexact proximal ALM and ADMM for a class of convex composite programming

On the equivalence of inexact proximal ALM and ADMM for a class of convex composite programming

Kinetic Euclidean Distance Matrices

A Fast Matrix Majorization-Projection Method for Penalized Stress Minimization With Box Constraints

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