Title :
Spectrum manipulation for improved resolution
Author :
Villalba, Michael J. ; Walker, Bruce K.
Author_Institution :
Dept. of Aeronaut. & Astronaut., MIT, Cambridge, MA, USA
fDate :
6/1/1989 12:00:00 AM
Abstract :
A novel approach to improving the frequency resolution of parametric power spectrum estimation for signals with rational spectra is discussed. Specifically, the effect of errors in the calculated autocorrelation values is considered. Analysis and numerical simulation reveal that the error sensitivity becomes acute when the poles are closely spaced, demonstrating one of the difficulties encountered when high-resolution spectrum estimates are required. To remedy this problem, two modified spectrum-estimation procedures are proposed. The first applies to situations where discrete-time techniques are used to estimate the spectra of continuous-time processes. It involves selecting the autocorrelation function sampling period to separate the poles. The second procedure involves desampling an autocorrelation sequence to separate closely spaced poles artificially. Numerical examples verify improved resolution for both procedures
Keywords :
correlation theory; error analysis; parameter estimation; poles and zeros; signal processing; spectral analysis; autocorrelation function sampling period; autocorrelation values; continuous-time processes; discrete-time techniques; error sensitivity; frequency resolution improvement; high-resolution spectrum estimates; numerical simulation; parametric power spectrum estimation; poles separation; rational spectra; signal processing; spectrum manipulation; spectrum-estimation procedures; Autocorrelation; Discrete Fourier transforms; Frequency estimation; Helium; Numerical simulation; Sampling methods; Signal resolution; Space technology; Spectral analysis; White noise;
Journal_Title :
Acoustics, Speech and Signal Processing, IEEE Transactions on
DOI :
10.1109/ASSP.1989.28055
