Title :
Architectures for phase variation compensation in AFR control
Author :
Meyer, Jorg ; Yurkovich, S. ; Midlam-Mohler, Shawn
Author_Institution :
Dept. of Electr. & Comput. Eng., Ohio State Univ., Columbus, OH, USA
fDate :
June 30 2010-July 2 2010
Abstract :
To counteract the binary nature of an exhaust gas oxygen sensor and to improve the efficiency of a three way catalyst, the delivered fueling quantity is typically dithered around stoichiometry for gasoline internal combustion engines. Determining whether the switching sensor reads rich or lean because of the dithering or a disturbance is very difficult. This problem is often overcome by estimating the plant delay and tracking a reference signal. Without an accurate delay estimate, however, the benefits of this type of control architecture are limited. This paper compares two switching sensor based control architectures, phase lock loop and duty cycle control, for tracking a periodic reference air-to-fuel ratio signal while overcoming the uncertainty of a dynamic plant delay estimate.
Keywords :
compensation; delay estimation; exhaust systems; fuel systems; gas sensors; internal combustion engines; petroleum; stoichiometry; AFR control; air-to-fuel ratio signal; control architecture; dithering; exhaust gas oxygen sensor; gasoline internal combustion engines; phase variation compensation; plant delay estimation; reference signal tracking; stoichiometry; switching sensor; Delay estimation; Error correction; Gas detectors; Internal combustion engines; Mechanical sensors; Petroleum; Phase locked loops; Sliding mode control; Three-term control; Tracking loops;
Conference_Titel :
American Control Conference (ACC), 2010
Conference_Location :
Baltimore, MD
Print_ISBN :
978-1-4244-7426-4
DOI :
10.1109/ACC.2010.5531230
