Joint Dwell Time and Bandwidth Optimization for Multi-Target Tracking in Radar Network Based on Low Probability of Intercept

Ding, Lintao; Shi, Chenguang; Qiu, Wei; Zhou, Jianjiang

doi:10.3390/s20051269

Cited by 10 publications

(14 citation statements)

References 27 publications

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“…Moreover, in order to better illustrate the superiority of the proposed CNS‐TRA strategy, its LPI performance and target tracking performance are compared with those of the following three benchmarks: Collaborative Power and Bandwidth Allocation (CPBA) strategy [26]: This method optimises the allocation of transmit power and effective bandwidth, whereas the dwell time of each PAR is fixed to 0.005 s. Joint Dwell Time and Bandwidth Allocation (JDTBA) strategy [18]: This method optimises the allocation of dwell time and effective bandwidth, whereas the transmit power of each PAR is fixed to 300W. Uniform Transmit Resource Allocation (UTRA) strategy: In this method, the transmit resource, i.e., transmit power, dwell time and effective bandwidth, are uniformly allocated to the designated radar nodes. …”

Section: Simulation Resultsmentioning

confidence: 99%

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Low probability of intercept‐based cooperative node selection and transmit resource allocation for multi‐target tracking in multiple radars architecture

Ding

Shi

Wang

et al. 2022

IET Signal Processing

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A low probability of intercept (LPI)-based cooperative node selection and transmit resource allocation (CNS-TRA) strategy is proposed for multi-target tracking in multiple radars architecture (MRA). The key idea of the proposed CNS-TRA strategy is to coordinate the radar node selection and the transmit resource that is, dwell time, transmit power, and effective bandwidth allocation to improve the LPI performance, under the constraints of predefined target tracking accuracy requirement and several resource budgets. By incorporating the above controllable parameters, the Bayesian Cramér-Rao lower bound is calculated and used as the accuracy metric for target tracking. Subsequently, this paper develops a fast and effective two-stage-based solution methodology to solve the resulting non-convex and non-linear optimisation problem. Specifically, the optimisation problem can be decomposed into two sub-problems, that is, the radar node selection sub-problem and the transmit resource allocation sub-problem. The active-set method and the interior point approach are utilised to solve those two sub-problems, respectively. Simulation results demonstrate that the CNS-TRA strategy has superiority over other existing algorithms and can achieve better LPI performance for MRA.

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Section: Simulation Resultsmentioning

confidence: 99%

“…Ding et al. [18] extend this work to joint dwell time and bandwidth optimisation case, which further improves LPI performance of radar network system. In the scenario of insufficient available power, Yuan et al.…”

Section: Introductionmentioning

confidence: 95%

Low probability of intercept‐based cooperative node selection and transmit resource allocation for multi‐target tracking in multiple radars architecture

Ding

Shi

Wang

et al. 2022

IET Signal Processing

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“…The time resource allocation is performed using kinematic estimation and prediction of target state parameters. Resource management solutions found in the literature mainly use the predicted states covariance matrix [3, 4], its expectation bound – Bayesian Cramer‐Rao lower bound (BCRLB) [5], the posterior CRLB (PCRLB) [6, 7] and predicted conditional CRLB (PC‐CRLB) [8].…”

Section: Introductionmentioning

confidence: 99%

Designing adaptive time resource management cost function for cognitive radar

Ghadian

Mofrad

Arand

2020

IET Radar, Sonar & Navigation

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“…

Networked radars can share different views of data from multiple stand-alone radars for fusion so as to improve the target tracking accuracy. The information fusion of multiple radars has the advantages of increasing the surveillance systems accuracy and enhancing the reliability [1][2][3][4].Before fusion, the data measured by local radars should be transformed to a common spatial coordinate system to acquire the reliable information of targets [5]. However, due to the deviation and measurement errors of radars, it is difficult to ensure the accuracy for tracking.

…”

mentioning

confidence: 99%

“…Networked radars can share different views of data from multiple stand-alone radars for fusion so as to improve the target tracking accuracy. The information fusion of multiple radars has the advantages of increasing the surveillance systems accuracy and enhancing the reliability [1][2][3][4].…”

mentioning

confidence: 99%

Range-Doppler domain spatial alignment for networked radars

Cong

Han

Sheng

et al. 2022

EURASIP J. Adv. Signal Process.

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An important prerequisite for the radar network detection is that the measurements from local radars are transformed to a common reference frame without systematic or registration errors. For the signal level alignment, only partial signals are available for global decision-making due to power and bandwidth limitations. In this paper, a low-communication-rate spatial alignment in range-Doppler domain is proposed for networked radars without the prior spatial information (positions and attitudes) of radars, which is different from the existing methods in the trajectory domain or echo domain for alignment. To reduce the radar-to-fusion-center communication-rate, the method of initial constant false alarm rate detection is used to censor the signals in range-Doppler domain from local radars. Based on the spatial alignment model for the networked radars in geometry, a maximization problem is formulated. The objective function is the cross-correlation between the range-Doppler domain signals from different local radars. The optimization problem is solved by a genetic algorithm. Simulation results show that the rotation matrix and translation vector are estimated, and the detection probability of the proposed algorithm is improved after alignment and fusion compared with state-of-art methods.

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Joint Dwell Time and Bandwidth Optimization for Multi-Target Tracking in Radar Network Based on Low Probability of Intercept

Cited by 10 publications

References 27 publications

Low probability of intercept‐based cooperative node selection and transmit resource allocation for multi‐target tracking in multiple radars architecture

Low probability of intercept‐based cooperative node selection and transmit resource allocation for multi‐target tracking in multiple radars architecture

Designing adaptive time resource management cost function for cognitive radar

Range-Doppler domain spatial alignment for networked radars

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