Title :
Orbital-Angular-Momentum-Based Electromagnetic Vortex Imaging
Author :
Kang Liu ; Yongqiang Cheng ; Zhaocheng Yang ; Hongqiang Wang ; Yuliang Qin ; Xiang Li
Author_Institution :
Coll. of Electron. Sci. & Eng., Nat. Univ. of Defense Technol., Changsha, China
Abstract :
A novel radar imaging technique based on orbital angular momentum (OAM) modulation is presented. First, the generation of electromagnetic (EM) vortex wave, which carries the OAM, using incrementally phased uniform circular array (UCA) is introduced, and factors that affect the phase-front distribution are analyzed. Subsequently, echo signal models of both multiple-in-multiple-out and multiple-in-single-out modes are established. The target images are obtained using the fast Fourier transform (FFT) and back-projection methods. Simulation results demonstrate that orbital angular momentum has the prospect for acquiring the azimuth information of radar target. The signal of both OAM modulation and frequency modulation can be used to obtain two-dimensional radar target image. The work can benefit the development of novel information-rich radar based on orbital angular momentum, as well as radar target recognition.
Keywords :
MIMO radar; angular momentum; antenna phased arrays; fast Fourier transforms; frequency modulation; radar imaging; EM vortex wave; FFT; OAM modulation; UCA; back-projection methods; echo signal models; fast Fourier transform; frequency modulation; incrementally phased uniform circular antenna array; information-rich radar; multiple-in-multiple-out modes; multiple-in-single-out modes; orbital-angular-momentum-based electromagnetic vortex imaging; phase-front distribution; radar imaging technique; radar target azimuth information; radar target recognition; two-dimensional radar target image; Arrays; Azimuth; Electromagnetic scattering; Electromagnetics; Imaging; Radar imaging; Electromagnetic vortex wave; orbital angular momentum; phase front; uniform circular antenna array;
Journal_Title :
Antennas and Wireless Propagation Letters, IEEE
DOI :
10.1109/LAWP.2014.2376970
