Title :
Zero-order quadrature-based phase-locked loop in aerospace applications
Author :
Losic, Novica A.
Author_Institution :
Honeywell Aerosp., Mississauga, ON, Canada
Abstract :
A method of minimizing dynamics and reducing phase error towards zero for arbitrary input frequency/phase profile while maintaining stability in a quadrature-based phase-locked loop is presented. Theoretically, the system transfer function becomes of zero order and the error is zero. Practically, the steady-state phase error approaches zero and the system is of minimum dynamics/order. The method is in synthesizing a feedforward control that is added to the quadrature-based phase-locked loop. The feedforward comprises a frequency-to-voltage converter based on a phase/frequency estimation while implementing an inverse feedforward control principle relative to the part of the feedback loop seen after the summing junction.
Keywords :
aerospace control; feedforward; frequency estimation; phase estimation; phase locked loops; stability; transfer functions; voltage-frequency convertors; aerospace application; feedforward control; frequency estimation; frequency-to-voltage converter; phase estimation; stability maintenance; steady-state phase error approach; system transfer function; zero-order quadrature-based phase-locked loop; Detectors; Feedforward neural networks; Frequency control; Frequency estimation; Phase locked loops; Steady-state; Transfer functions; Phase-locked loops; motor/generator control in aero-space applications; tracking control;
Conference_Titel :
Vehicle Power and Propulsion Conference (VPPC), 2011 IEEE
Conference_Location :
Chicago, IL
Print_ISBN :
978-1-61284-248-6
Electronic_ISBN :
Pending
DOI :
10.1109/VPPC.2011.6043033
