Title :
Frequency estimation accuracy of ROCKET
Author :
Witzgall, Hanna E. ; Ogle, William C. ; Goldstein, J.Scott
Author_Institution :
Sci. Applications Int. Corp., Chantilly, VA, USA
Abstract :
We assess the frequency estimation accuracy of the recently introduced reduced rank autoregressive linear predictor called reduced order correlation kernel estimation technique (ROCKET). We compare the frequency estimation performance of ROCKET to both the conventional full rank autoregressive (FR-AR) method and the theoretical limit imposed by the Cramer-Rao bound (CRB). The analysis includes estimation accuracy as a function of signal-to-noise ratio (SNR), data length, and subspace rank. Simulations reveal that ROCKET can approach the CRB for a much greater range of SNR levels and for shorter data sequences than FR-AR. Perhaps more importantly, ROCKET´s performance is shown to be very robust to subspace rank selection. This means that a priori knowledge of the upperbound of the number of frequencies present is not crucial to this reduced rank algorithm. Finally, it is shown that a small frequency estimation bias appears when the subspace rank is well below the signal rank.
Keywords :
autoregressive processes; correlation theory; frequency estimation; prediction theory; reduced order systems; ROCKET; data length; estimation accuracy; frequency estimation accuracy; reduced order correlation kernel estimation technique; reduced rank autoregressive linear predictor; signal-to-noise ratio; subspace rank; Discrete Fourier transforms; Frequency estimation; Kernel; Robustness; Rockets; Signal analysis; Signal processing algorithms; Signal to noise ratio; Spectral analysis; White noise;
Conference_Titel :
Radar Conference, 2002. Proceedings of the IEEE
Print_ISBN :
0-7803-7357-X
DOI :
10.1109/NRC.2002.999685
