Joint Adaptive Sampling Interval and Power Allocation for Maneuvering Target Tracking in a Multiple Opportunistic Array Radar System

Han, Qing; Pan, Minghai; Long, Weijun; Liang, Zhou; Shan, Chenggang

doi:10.3390/s20040981

Cited by 10 publications

(5 citation statements)

References 36 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Shaghaghi et al introduced machine learning into the multi-channel, multi-function radar resource management problem, solved the optimal solution of the task scheduling problem by using the branch and bound algorithm, and used machine learning to reduce the computational complexity and maximize the utilization of time and other resources [15]. Han et al proposed a joint adaptive sampling interval and power allocation (JASIPA) scheme based on opportunistic programming constraint (OCP) [16]. However, most of the existing low radiation energy control methods are designed for conventional moving targets, and there are few studies on high-maneuvering targets.…”

Section: Introductionmentioning

confidence: 99%

Adaptive Tracking of High-Maneuvering Targets Based on Multi-Feature Fusion Trajectory Clustering: LPI’s Purpose

Lei

Chen

Ding

et al. 2022

Sensors

View full text Add to dashboard Cite

Since the passive sensor has the property that it does not radiate signals, the use of passive sensors for target tracking is beneficial to improve the low probability of intercept (LPI) performance of the combat platform. However, for the high-maneuvering targets, its motion mode is unknown in advance, so the passive target tracking algorithm using a fixed motion model or interactive multi-model cannot match the actual motion mode of the maneuvering target. In order to solve the problem of low tracking accuracy caused by the unknown motion model of high-maneuvering targets, this paper firstly proposes a state transition matrix update-based extended Kalman filter (STMU-EKF) passive tracking algorithm. In this algorithm, the multi-feature fusion-based trajectory clustering is proposed to estimate the target state, and the state transition matrix is updated according to the estimated value of the motion model and the observation value of multi-station passive sensors. On this basis, considering that only using passive sensors for target tracking cannot often meet the requirements of high target tracking accuracy, this paper introduces active radar for indirect radiation and proposes a multi-sensor collaborative management model based on trajectory clustering. The model performs the optimal allocation of active radar and passive sensors by judging the accumulated errors of the eigenvalue of the error covariance matrix and makes the decision to update the state transition matrix according to the magnitude of the fluctuation parameter of the error difference between the prediction value and the observation value. The simulation results verify that the proposed multi-sensor collaborative target tracking algorithm can effectively improve the high-maneuvering target tracking accuracy to satisfy the radar’s LPI performance.

show abstract

Section: Introductionmentioning

confidence: 99%

Adaptive Tracking of High-Maneuvering Targets Based on Multi-Feature Fusion Trajectory Clustering: LPI’s Purpose

Lei

Chen

Ding

et al. 2022

Sensors

View full text Add to dashboard Cite

show abstract

“…The unidentical coding artificial magnetic conductor ground is structured to reduce the backscattering energy level of the antenna array, such as a chessboard‐like configuration, and a coaxial feed is given separately to each array. [ 12–16 ]…”

Section: Introductionmentioning

confidence: 99%

“…A wideband backscattering decrease of the antenna is achieved by loading a Jerusalem chessboard setup consisting of crosses and squares patches; 10 dB backscattering reduction is achieved by 65% comparative bandwidth. [ 17–29 ] Using a chessboard‐arranged metamaterial superstrate developed using a frequency‐selective surface, a small scattering antenna is acquired. The 10 dB backscattering is 55% relative bandwidth.…”

Section: Introductionmentioning

confidence: 99%

Coding Artificial Magnetic Conductor Ground and Their Application to High‐Gain, Wideband Radar Cross‐Section Reduction of a 2×2 Antenna Array

Saleem

Saifullah

2021

Physica Status Solidi (a)

View full text Add to dashboard Cite

A new technique is proposed for designing a low‐scattering 2 × 2 antenna array using strategic coding metasurface ground for wideband bistatic and monostatic backscattered energy level reduction. Two various artificial magnetic conductor (AMC) units cells are organized like a chessboard to obtain an effective 180° ± 37° reflection phase difference over a broadband frequency range. The low‐backscattering microstrip antenna array is achieved based on the destructive interference theory and diffusion property of AMC unit cells. Simulations show that the proposed antenna array has a considerable backscattering field level reduction of 4.7–18 GHz for both the x‐ and y‐polarization incident waves. It should also be noted that the maximum reduction of backscattered energy at a frequency of 7.2 GHz is −18 dB. The bistatic backscattering performance of the antenna is also given at different frequencies. Both a reference and a proposed prototype are fabricated, and the results are analyzed. Measurements of the fabricated prototype coincide well with simulations.

show abstract

“…The difference in structure from conventional unmanned helicopters is that unmanned tandem helicopters have no slender tail boom, with two rotors of the same size arranged in the longitudinal direction, one in the front and one in the back, and the rotors have the same rotation speed and opposite rotation directions [ 21 , 22 , 23 ]. In order to ensure the accuracy of simultaneous localization and mapping (SLAM) in the millimeter-wave band [ 24 , 25 ], a millimeter-wave radar SLAM assisted by the RCS feature of the target and inertial measurement unit is presented. With the extensive equipment of dual-band radars on various weapon platforms, the study of the electromagnetic scattering characteristics of helicopters in the X-band has also become important.…”

Section: Introductionmentioning

confidence: 99%

X-Band Radar Cross-Section of Tandem Helicopter Based on Dynamic Analysis Approach

Zhou

Huang

2021

Sensors

View full text Add to dashboard Cite

In order to study the radar signature of a tandem helicopter in the X-band, a dynamic analysis approach (DAA) is presented to determine its radar cross-section (RCS) under different influence factors. The basic passage time, rotation speed, observation angle, rotor disk inclination, fuselage attitude angle and Doppler feature are studied and discussed in detail. The results show that the dynamic characteristics of the rotor RCS will bring significant changes to the peak and average values of the helicopter RCS. Within a given observation angle range, a larger elevation angle is undesirable for helicopter stealth. The inclination of the rotor disc will affect the many small peaks and local fluctuations of the helicopter RCS. The positively increased attitude angle will have an undesirable effect on the average RCS and dynamic characteristics of the helicopter. The DAA is feasible and effective for studying the radar cross-section of a tandem helicopter.

show abstract

Joint Adaptive Sampling Interval and Power Allocation for Maneuvering Target Tracking in a Multiple Opportunistic Array Radar System

Cited by 10 publications

References 36 publications

Adaptive Tracking of High-Maneuvering Targets Based on Multi-Feature Fusion Trajectory Clustering: LPI’s Purpose

Adaptive Tracking of High-Maneuvering Targets Based on Multi-Feature Fusion Trajectory Clustering: LPI’s Purpose

Coding Artificial Magnetic Conductor Ground and Their Application to High‐Gain, Wideband Radar Cross‐Section Reduction of a 2×2 Antenna Array

X-Band Radar Cross-Section of Tandem Helicopter Based on Dynamic Analysis Approach

Contact Info

Product

Resources

About