Your search keyword '"traditional phased array radars"' showing total 2 results

1. Fast mesh forming for distributed digital array radar

Author

Jin Guanghu, Chen Tao, and Dong Zhen

Subjects

array signal processing, phased array radar, fast Fourier transforms, radar signal processing, RADBASE data, Cartesian coordinates, polar formatted plane, range profile, fast Fourier transform, traditional multiple beam forming, fast mesh forming method, space mesh, traditional phased array radars, multiple modes, DDAR, distributed digital array radar, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Distributed digital array radar (DDAR) can operate in multiple modes and perform multiple functions. Compared with traditional phased array radars, the performance advantages of DDAR are obvious in many aspects. One of them is that DDAR can form space mesh in a wide scope. This article proposes a new fast mesh forming method. Unlike traditional multiple beam forming, the authors’ algorithm can form a mesh along range and azimuth. First, the range profile is obtained based on fast Fourier transform. Second, the mesh forming is divided into several steps that are accomplished in polar formatted plane. Finally, the polar formatted result is transformed into Cartesian coordinates. The authors tested the method using RADBASE data, which shows that the authors’ algorithm has good performance.

Published

2019

2. Fast mesh forming for distributed digital array radar.

Author

Guanghu, Jin, Tao, Chen, and Zhen, Dong

Subjects

RADAR, CARTESIAN coordinates, FOURIER transforms, AZIMUTH, ALGORITHMS

Abstract

Distributed digital array radar (DDAR) can operate in multiple modes and perform multiple functions. Compared with traditional phased array radars, the performance advantages of DDAR are obvious in many aspects. One of them is that DDAR can form space mesh in a wide scope. This article proposes a new fast mesh forming method. Unlike traditional multiple beam forming, the authors' algorithm can form a mesh along range and azimuth. First, the range profile is obtained based on fast Fourier transform. Second, the mesh forming is divided into several steps that are accomplished in polar formatted plane. Finally, the polar formatted result is transformed into Cartesian coordinates. The authors tested the method using RADBASE data, which shows that the authors' algorithm has good performance. [ABSTRACT FROM AUTHOR]

Published

2019