Title :
Phase-shift-based time-delay estimators for proximity acoustic sensors
Author :
Li, Xi ; Larsson, Erik G. ; Sheplak, Mark ; Li, Jian
Author_Institution :
Dept. of Electr. & Comput. Eng., Florida Univ., Gainesville, FL, USA
fDate :
1/1/2002 12:00:00 AM
Abstract :
Time-delay estimation is important in a wide range of applications in oceanic engineering. In this paper, we present a novel time-delay estimation algorithm based on maximum likelihood theory for the case that the measurements are corrupted by colored or nonuniform zero-mean Gaussian noise. It turns out that the likelihood function associated with the problem is highly oscillatory, and we propose a computationally efficient technique to maximize this function. Our algorithm first obtains an initial estimate based on a smooth approximate cost function, and then refines this estimate based on the true cost function. Simulation results show that our estimator outperforms a traditional phaseshift based estimator, and that the estimation error approaches the Cramer-Rao bound when the SNR increases without bound
Keywords :
Gaussian noise; acoustic signal processing; delay estimation; maximum likelihood estimation; spectral analysis; ultrasonic transducers; underwater sound; Cramer-Rao bound; cavity thickness; colored noise; data model; direct matching method; hard acoustic boundary; highly oscillatory function; maximum likelihood theory; nonlinear optimization problem; nonuniform zero-mean Gaussian noise; oceanic engineering; parsimony principle; phase-shift method; phase-shift-based time-delay estimators; proximity acoustic sensors; smooth approximate cost function; spectral estimation; transmitted ultrasonic signal; true cost function; underwater supercavitating vehicles; Acoustic measurements; Computational modeling; Cost function; Estimation error; Gaussian noise; Maximum likelihood estimation; Noise measurement; Oceanic engineering and marine technology; Phase estimation; Sea measurements;
Journal_Title :
Oceanic Engineering, IEEE Journal of
