Globally Optimized TDOA High-Frequency Source Localization Based on Quasi-Parabolic Ionosphere Modeling and Collaborative Gradient Projection

Research output: Journal Publications and ReviewsRGC 21 - Publication in refereed journalpeer-review

8 Scopus Citations
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Detail(s)

Original languageEnglish
Pages (from-to)580-590
Number of pages11
Journal / PublicationIEEE Transactions on Aerospace and Electronic Systems
Volume59
Issue number1
Online published24 Jun 2022
Publication statusPublished - Feb 2023

Abstract

We investigate the problem of high frequency (HF) source localization using the time-difference-of-arrival (TDOA) observations of ionosphere-refracted radio rays based on quasi-parabolic (QP) modeling. An unresolved but pertinent issue in such a field is that the existing gradient-type scheme can easily get trapped in local optima for practical use. This will lead to the difficulty in initializing the algorithm and finally degraded positioning performance if the starting point is inappropriately selected. In this paper, we develop a collaborative gradient projection (GP) algorithm in order to globally solve the highly nonconvex QP-based TDOA HF localization problem. The metaheuristic of particle swarm optimization (PSO) is exploited for information sharing among multiple GP models, each of which is guaranteed to work out a critical point solution to the simplified maximum likelihood formulation. Random mutations are incorporated to avoid the early convergence of PSO. Rather than treating the geolocation of HF transmitter as a pure optimization problem, we further provide workarounds for addressing the possible impairments and challenges when the proposed technique is applied in practice. Numerical results demonstrate the effectiveness of our PSO-assisted reinitialization strategy in achieving the global optimality, and the superiority of our method over its competitor in terms of positioning accuracy.

Research Area(s)

  • Collaboration, Earth, Gradient projection, Hafnium, Ionosphere, localization, Location awareness, Maximum likelihood estimation, particle swarm optimization, quasi-parabolic model, Sensors, time-difference-of-arrival

Citation Format(s)

Globally Optimized TDOA High-Frequency Source Localization Based on Quasi-Parabolic Ionosphere Modeling and Collaborative Gradient Projection. / XIONG, Wenxin; SCHINDELHAUER, Christian; SO, Hing Cheung.
In: IEEE Transactions on Aerospace and Electronic Systems, Vol. 59, No. 1, 02.2023, p. 580-590.

Research output: Journal Publications and ReviewsRGC 21 - Publication in refereed journalpeer-review