A Terrain Information Constrained Semidefinite Relaxation Method for Doppler Shift Based Source Localization

Deng, Lijuan; Wei, Ping; Zhang, Zhan; Chen, Ningkang; Liao, Hongshu; Sun, Wen

doi:10.1109/igarss.2018.8518761

Cited by 3 publications

(1 citation statement)

References 14 publications

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“…Recently, some Doppler-shift positioning methods based on pseudo-linear equations have been proposed in the literature. The works in [28][29][30] propose FOA-based source localisation methods based on semidefinite relaxation (SDR) technique. The SDR-based approaches do not reply on good initial guess and can avoid local convergence and divergence.…”

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confidence: 99%

Novel frequency of arrival‐based emitter localisation methods based on multiple moving observers

Wang

Yin

Chen³

et al. 2022

IET Signal Processing

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It is well known that the Doppler frequency shift contains the emitter location information. The problem of emitter location based on frequency of arrival (FOA) measurements of multiple moving observers is focussed. In contrast to most relevant works, the newly proposed positioning methods consider the influence of signal frequency deviation due to source instability and present two mathematical models of the frequency deviation. The first model assumes that the frequency offset is a small random parameter. A two-stage closed-form location method (called method a) is proposed. In stage 1, a set of pseudo-linear equations are established according to the geometric relationship between the observers and emitter, so as to obtain an intermediate estimate of source position. Stage 2 returns to the original FOA measurement model and uses the estimation result in stage 1 to construct the second set of pseudo-linear equations, yielding the final positioning result. The second model assumes that the signal frequency deviation is a large deterministic parameter. We propose an alternative two-stage localisation method (called method b). In stage 1, a decoupling optimisation algorithm is developed based on the pseudo-linear equations derived in stage 1 of method a, and intermediate estimates of the source position and frequency deviation are obtained successively. Stage 2 returns to the original FOA measurement model again and forms the second set of pseudo-linear equations, yielding the final closed-form solutions of emitter position and frequency offset. Both methods are proved analytically to achieve the Cramér-Rao bound (CRB) under the moderate noise level. Simulation results demonstrate the superior performance of the new methods. K E Y W O R D Sclosed-form solution, Cramér-Rao bound (CRB), Doppler shift, emitter localisation, frequency-of-arrival (FOA), performance analysis, pseudo-linear equation | INTRODUCTIONIt is well known that emitter location technology has been widely applied in industrial and information fields, such as smart city, automatic driving, navigation and telemetry, emergency rescue, safety management, etc. It is also an indispensable supporting technology in the field of national defence security, such as target monitoring, situational awareness and strategic early warning. Emitter location technology is usually called passive location technology [1][2][3]. Generally, passive positioning system can be divided into single-station positioning system [4] and multi-station positioning system [5] according to the number of observers. In this work, we deal with the multi-station location method, because it can obtain more measurement information to improve the localisation accuracy.Azimuth-of-arrival (AOA) [6-8] and time-difference-ofarrival (TDOA) [9][10][11] are two kinds of measurements that are commonly used in multi-station positioning approaches. However, it is noteworthy that the former requires an antennaThis is an open access article under the terms of the Creative Commons Attribution License, wh...

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confidence: 99%