A computational geometry method for optimal resource allocation in network localization

Wireless network localization (WNL) is an emerging paradigm for providing high-accuracy positional information in GPS-challenged environments. The localization performance of a node in WNL is determined by the allocation of transmit resources among its neighboring nodes. To achieve the best localization performance, we develop a computational geometry framework for optimal resource allocation in WNL. We first determine an affine map that transforms each resource allocation strategy into a point in 3-D Euclidian space. By exploiting geometric properties of these image points, we prove the sparsity property of the optimal resource allocation vector, i.e., the optimal localization performance can be achieved by allocating resources to only a small subset of neighboring nodes. Moreover, these geometric properties enable the reduction of the search space for optimal solutions, based on which we design efficient resource allocation strategies. Numerical results show that the proposed strategies can achieve significant improvements in both localization performance and computation efficiency. Our approach provides a new methodology for resource allocation in network localization, yielding exact optimal solutions rather than ϵ-approximate solutions.

[1]  Moe Z. Win,et al.  Fundamental Limits of Wideband Localization— Part I: A General Framework , 2010, IEEE Transactions on Information Theory.

[2]  Moe Z. Win,et al.  Fundamental Limits of Wideband Localization— Part II: Cooperative Networks , 2010, IEEE Transactions on Information Theory.

[3]  Tao Wang,et al.  Ranging Energy Optimization for Robust Sensor Positioning Based on Semidefinite Programming , 2009, IEEE Transactions on Signal Processing.

[4]  Wenhan Dai,et al.  Geometric methods for optimal resource allocation in wireless network localization , 2014 .

[5]  2015 IEEE Wireless Communications and Networking Conference Workshops, WCNC Workshops 2015, New Orleans, LA, USA, March 9-12, 2015 , 2015, WCNC Workshops.

[6]  Moe Z. Win,et al.  Network localization and navigation via cooperation , 2011, IEEE Communications Magazine.

[7]  Hisashi Kobayashi,et al.  Analysis of wireless geolocation in a non-line-of-sight environment , 2006, IEEE Transactions on Wireless Communications.

[8]  Moe Z. Win,et al.  Ranging With Ultrawide Bandwidth Signals in Multipath Environments , 2009, Proceedings of the IEEE.

[9]  Lisa Turner,et al.  Applications of Second Order Cone Programming , 2012 .

[10]  Moe Z. Win,et al.  Power Optimization for Network Localization , 2013, IEEE/ACM Transactions on Networking.

[11]  Gordon L. Stüber,et al.  Overview of radiolocation in CDMA cellular systems , 1998, IEEE Commun. Mag..

[12]  H. Vincent Poor,et al.  Power Allocation Strategies for Target Localization in Distributed Multiple-Radar Architectures , 2011, IEEE Transactions on Signal Processing.

[13]  Moe Z. Win,et al.  Position Error Bound for UWB Localization in Dense Cluttered Environments , 2006, 2006 IEEE International Conference on Communications.

[14]  Jean-Benoît Pierrot,et al.  Joint distributed synchronization and positioning in UWB ad hoc networks using TOA , 2006, IEEE Transactions on Microwave Theory and Techniques.