Title :
Spline function approximation for velocimeter Doppler frequency measurement
Author :
Savakis, Andreas E. ; Stoughton, John W. ; Kanetkar, Sharad V.
Author_Institution :
Dept. of Electr. Eng., North Carolina State Univ., Raleigh, NC, USA
fDate :
8/1/1989 12:00:00 AM
Abstract :
A spline function approximation approach for measuring the Doppler spectral peak frequency in a laser Doppler velocimeter system is presented. The processor is designed for signal bursts with mean Doppler shift frequencies up to 100 MHz, input turbulence up to 20%, and photon counts as low as 300. The frequency-domain processor uses a bank of digital bandpass filters for the capture of the energy spectrum of each signal burst. The average values of the filter output energies, as a function of normalized frequency, are modeled as deterministic spline functions which are linearly weighted to evaluate the spectral peak location associated with the Doppler shift. The weighting coefficients are chosen to minimize the mean square error. Performance evaluation by simulation yields average errors in estimating mean Doppler frequencies within 0.5% for poor signal-to-noise conditions associated with a low photon count of 300 photons/burst
Keywords :
Doppler effect; approximation theory; band-pass filters; computerised signal processing; digital filters; digital simulation; frequency measurement; laser velocimeters; physics computing; splines (mathematics); 100 MHz; deterministic spline functions; digital bandpass filters; frequency-domain processor; laser Doppler velocimeter; mean Doppler shift frequencies; mean square error; photon counts; signal bursts; spectral peak frequency; spline function approximation; velocimeter Doppler frequency measurement; weighting coefficients; Band pass filters; Doppler shift; Energy capture; Frequency estimation; Frequency measurement; Function approximation; Process design; Signal design; Signal processing; Spline;
Journal_Title :
Instrumentation and Measurement, IEEE Transactions on
