Title :
Focusing Highly Squinted Data Using the Extended Nonlinear Chirp Scaling Algorithm
Author :
Gao-gao, Liu ; Lin-rang, Zhang ; Nan, Liu ; Guang-feng, Chen ; Yan, Zhang
Author_Institution :
Nat. Key Lab. for Radar Signal Process., Xidian Univ., Xi´´an, China
Abstract :
The most serious problem in processing highly squinted data is the strong range-Doppler coupling, which can be reduced by the linear range cell migration correction (LRCMC). After the LRCMC, however, targets with different azimuth frequency modulation (FM) rates are moved into the same range cell, blocking the efficient azimuth compression. In this letter, a new algorithm to equalize the FM rates is presented, which is referred to as azimuth extended nonlinear chirp scaling. The key is to derive a new perturbation function to handle the problem while introducing a negligible residual phase. The proposed method outperforms the existing algorithms, particularly in large bandwidth cases. Numerical simulations illustrate the performance of the proposed algorithm.
Keywords :
Doppler radar; FM radar; numerical analysis; perturbation theory; synthetic aperture radar; LRCMC; azimuth FM rate; azimuth compression; azimuth extended nonlinear chirp scaling algorithm; azimuth frequency modulation rate; highly squinted SAR data; linear range cell migration correction; numerical simulation; perturbation function; strong range-Doppler coupling; Azimuth; Bandwidth; Chirp; Frequency modulation; Geometry; Signal processing algorithms; Synthetic aperture radar; Frequency modulation (FM); highly squinted; nonlinear chirp scaling (NLCS); perturbation function; synthetic aperture radar (SAR);
Journal_Title :
Geoscience and Remote Sensing Letters, IEEE
DOI :
10.1109/LGRS.2012.2203785
