Title :
Super resolution time delay estimation via MODE-WRELAX
Author :
Wu, Renbiao ; Li, Jian ; Liu, Zheng-She
Author_Institution :
Dept. of Electr. & Comput. Eng., Florida Univ., Gainesville, FL, USA
fDate :
1/1/1999 12:00:00 AM
Abstract :
We consider estimating time delays and amplitudes (real- or complex-valued) from the superposition of very closely spaced signals with known shapes. The well-known high resolution MODE (Method Of Direction Estimation) algorithm, which was originally proposed for angle estimation in array processing, is modified and used with our efficient time delay estimation method WRELAX (Weighted Fourier transform and RELAXation based) algorithm to deal with this problem. The proposed method is referred to as MODE-WRELAX. MODE-WRELAX provides better accuracy than MODE and higher resolution than WRELAX. Moreover, it can be used for both complex- and real-valued signals (including those with highly oscillatory correlation functions). Numerical results show that the MODE-WRELAX estimates can approach the corresponding Cramer-Rao bound. Efficient implementation of the algorithm is also discussed
Keywords :
Fourier transforms; adaptive estimation; convergence of numerical methods; correlation theory; data models; delay estimation; least squares approximations; minimisation; radar resolution; radar theory; relaxation theory; signal resolution; sonar signal processing; 1D optimization; Cramer-Rao bound; MODE-WRELAX; active sonar; complex-valued signals; convergence; data model; efficient algorithm implementation; ground penetrating radar; high range resolution radar; highly oscillatory correlation functions; modified method of direction estimation algorithm; multidimensional optimization; nonlinear least squares; real-valued signals; relaxation based algorithm; superposition; superresolution time delay estimation; very closely spaced signals; weighted Fourier transform; Amplitude estimation; Array signal processing; Convergence; Cost function; Delay effects; Delay estimation; Fourier transforms; Military computing; Shape; Signal resolution;
Journal_Title :
Aerospace and Electronic Systems, IEEE Transactions on
