A Range-Free Node Localization Method for Anisotropic Wireless Sensor Networks with Sparse Anchors
Yong Jin, Junfang Leng, Lin Zhou, Yu Jiang, Qian Wei
TL;DR
This work introduces an adaptive weighted method, termed AW-MinMax, for range-free node localization, which employs a Sequential Convex Approximation (SCA) algorithm that utilizes first-order Taylor expansion for iterative refinement.
Abstract
In sensor networks characterized by irregular layouts and poor connectivity, anisotropic properties can significantly reduce the accuracy of distance estimation between nodes, consequently impairing the localization precision of unidentified nodes. Since distance estimation is contingent upon the multi-hop paths between anchor node pairs, assigning differential weights based on the reliability of these paths could enhance localization accuracy. To address this, we introduce an adaptive weighted method, termed AW-MinMax, for range-free node localization. This method involves constructing a weighted mean nodes localization model, where each multi-hop path weight is inversely proportional to the number of hops. Despite the model's inherent non-convexity and non-differentiability, it can be reformulated into an optimization model with convex objective functions and non-convex constraints through matrix transformations. To resolve these constraints, we employ a Sequential Convex Approximation (SCA) algorithm that utilizes first-order Taylor expansion for iterative refinement. Simulation results validate that our proposed algorithm substantially improves stability and accuracy in estimating range-free node locations.