DocumentCode
1437573
Title
An efficient 3-D near-field ISAR algorithm
Author
Fortuny, Joaquim
Author_Institution
Space Appl. Inst., Joint Res. Centre of the Eur. Comm., Iapra, Italy
Volume
34
Issue
4
fYear
1998
fDate
10/1/1998 12:00:00 AM
Firstpage
1261
Lastpage
1270
Abstract
This paper presents a new three-dimensional (3-D) near-field inverse synthetic aperture radar (ISAR) imaging technique. A 3-D ISAR image can be obtained by processing coherently the backscattered fields as a function of the frequency and two rotation angles about axes which are mutually orthogonal. Most of the existing ISAR algorithms are based on the Fourier transform and as such can tolerate only small amounts of wavefront curvature. Wavefront curvature must be taken into account when imaging an object in the near-field. Near-field ISAR imaging of large objects using a direct Fourier inversion may result in images which are increasingly unfocused at points which are more distant from the center of rotation. An algorithm based on an azimuth convolution between a near-field focusing function and the frequency domain backscattered fields is discussed. This convolution is efficiently implemented by using fast Fourier transform (FFT) techniques. Furthermore, in order to further alleviate the computational load of the algorithm, the discrete Fourier transform (DFT) of the focusing function is evaluated by means of the stationary phase method. Experimental results show that this technique is precise and virtually impulse invariant
Keywords
computational complexity; discrete Fourier transforms; fast Fourier transforms; focusing; image processing; radar imaging; synthetic aperture radar; 3D near-field ISAR algorithm; DFT; Fourier transform; ISAR algorithms; azimuth convolution; computational load; direct Fourier inversion; discrete Fourier transform; fast Fourier transform; focusing function; frequency domain backscattered fields; inverse synthetic aperture radar imaging; near-field focusing function; rotation angles; stationary phase method; wavefront curvature; Azimuth; Convolution; Discrete Fourier transforms; Fast Fourier transforms; Focusing; Fourier transforms; Frequency domain analysis; Interpolation; Inverse synthetic aperture radar; Radar imaging;
fLanguage
English
Journal_Title
Aerospace and Electronic Systems, IEEE Transactions on
Publisher
ieee
ISSN
0018-9251
Type
jour
DOI
10.1109/7.722713
Filename
722713
Link To Document