Distributed Scaled Proximal ADMM Algorithms for Cooperative Localization in WSNs

Distributed cooperative localization in wireless networks is a challenging problem since it typically requires solving a large-scale nonconvex and nonsmooth optimization problem. In this article, we reformulate the classic cooperative localization problem as a smooth and constrained nonconvex minimization problem while its loss function is separable over nodes. By utilizing the structure of the reformulation, we propose two novel scaled proximal alternating direction method of multipliers (SP-ADMM) algorithms, which can be implemented in a distributed manner. Compared with the classic semi-definite programming relaxation techniques, the proposed algorithms can provide more accurate position estimates with significantly lower computation complexity. The associated theoretical analysis shows that our algorithms globally converge to a KKT point of the reformulated problem and a critical point of the original problem, with a favorable sublinear $\boldsymbol{\mathcal{O}}\left(\mathbf{1}/\boldsymbol{T}\right)$ convergence rate, where $\boldsymbol{T}$ is the iteration counter. Numerical experiments have consistently shown that the proposed SP-ADMM algorithms are superior to state-of-the-art methods in terms of localization accuracy and computational complexity across all tested scenarios, varying network size, number of anchors, average number of neighbors, and noise variance levels.
Source: IEEE Transactions on Signal Processing - Category: Biomedical Engineering Source Type: research