Your search keyword '"Covariance Matrix Fusion Method"' showing total 3 results

1. Target Localization Based on Bistatic T/R Pair Selection in GNSS-Based Multistatic Radar System

Author

Yu’e Shao, Hui Ma, Shenghua Zhou, Xue Wang, Michail Antoniou, and Hongwei Liu

Subjects

target localization, T/R pair selection, multistatic radar, Covariance Matrix Fusion Method, Convex Hull Optimization Method, Science

Abstract

To cope with the increasingly complex electromagnetic environment, multistatic radar systems, especially the passive multistatic radar, are becoming a trend of future radar development due to their advantages in anti-electronic jam, anti-destruction properties, and no electromagnetic pollution. However, one problem with this multi-source network is that it brings a huge amount of information and leads to considerable computational load. Aiming at the problem, this paper introduces the idea of selecting external illuminators in the multistatic passive radar system. Its essence is to optimize the configuration of multistatic T/R pairs. Based on this, this paper respectively proposes two multi-source optimization algorithms from the perspective of resolution unit and resolution capability, the Covariance Matrix Fusion Method and Convex Hull Optimization Method, and then uses a Global Navigation Satellite System (GNSS) as an external illuminator to verify the algorithms. The experimental results show that the two optimization methods significantly improve the accuracy of multistatic positioning, and obtain a more reasonable use of system resources. To evaluate the algorithm performance under large number of transmitting/receiving stations, further simulation was conducted, in which a combination of the two algorithms were applied and the combined algorithm has shown its effectiveness in minimize the computational load and retain the target localization precision at the same time.

Published

2021

2. Target Localization Based on Bistatic T/R Pair Selection in GNSS-based Multistatic Radar System

Author

Shenghua Zhou, Xue Wang, Hui Ma, Michail Antoniou, Yu’e Shao, and Hongwei Liu

Subjects

Computer science, Electromagnetic environment, Real-time computing, 0211 other engineering and technologies, Satellite system, 02 engineering and technology, law.invention, Passive radar, T/R pair selection, 0203 mechanical engineering, law, multistatic radar, target localization, Covariance Matrix Fusion Method, Convex Hull Optimization Method, Radar, lcsh:Science, 021101 geological & geomatics engineering, 020301 aerospace & aeronautics, Covariance matrix, Bistatic radar, GNSS applications, Multistatic radar, General Earth and Planetary Sciences, lcsh:Q

Abstract

To cope with the increasingly complex electromagnetic environment, multistatic radar systems, especially the passive multistatic radar, are becoming a trend of future radar development due to their advantages in anti-electronic jam, anti-destruction properties, and no electromagnetic pollution. However, one problem with this multi-source network is that it brings a huge amount of information and leads to considerable computational load. Aiming at the problem, this paper introduces the idea of selecting external illuminators in the multistatic passive radar system. Its essence is to optimize the configuration of multistatic T/R pairs. Based on this, this paper respectively proposes two multi-source optimization algorithms from the perspective of resolution unit and resolution capability, the Covariance Matrix Fusion Method and Convex Hull Optimization Method, and then uses a Global Navigation Satellite System (GNSS) as an external illuminator to verify the algorithms. The experimental results show that the two optimization methods significantly improve the accuracy of multistatic positioning, and obtain a more reasonable use of system resources. To evaluate the algorithm performance under large number of transmitting/receiving stations, further simulation was conducted, in which a combination of the two algorithms were applied and the combined algorithm has shown its effectiveness in minimize the computational load and retain the target localization precision at the same time.

Published

2021

3. Target Localization Based on Bistatic T/R Pair Selection in GNSS-Based Multistatic Radar System.

Author

Shao, Yu'e, Ma, Hui, Zhou, Shenghua, Wang, Xue, Antoniou, Michail, Liu, Hongwei, and Santi, Fabrizio

Subjects

*BISTATIC radar, *GLOBAL Positioning System, *PASSIVE radar, *RADAR, *COVARIANCE matrices

Abstract

To cope with the increasingly complex electromagnetic environment, multistatic radar systems, especially the passive multistatic radar, are becoming a trend of future radar development due to their advantages in anti-electronic jam, anti-destruction properties, and no electromagnetic pollution. However, one problem with this multi-source network is that it brings a huge amount of information and leads to considerable computational load. Aiming at the problem, this paper introduces the idea of selecting external illuminators in the multistatic passive radar system. Its essence is to optimize the configuration of multistatic T/R pairs. Based on this, this paper respectively proposes two multi-source optimization algorithms from the perspective of resolution unit and resolution capability, the Covariance Matrix Fusion Method and Convex Hull Optimization Method, and then uses a Global Navigation Satellite System (GNSS) as an external illuminator to verify the algorithms. The experimental results show that the two optimization methods significantly improve the accuracy of multistatic positioning, and obtain a more reasonable use of system resources. To evaluate the algorithm performance under large number of transmitting/receiving stations, further simulation was conducted, in which a combination of the two algorithms were applied and the combined algorithm has shown its effectiveness in minimize the computational load and retain the target localization precision at the same time. [ABSTRACT FROM AUTHOR]

Published

2021