Title :
Individual Cylinder Air–Fuel Ratio Control Using Fourier Analysis
Author :
Schick, Wolfgang ; Onder, Christopher ; Guzzella, Lino
Author_Institution :
Dept. of Mech. & Process Eng., ETH Zurich, Zurich, Switzerland
Abstract :
Based on Fourier analysis, a general concept for the cylinder imbalance control problem with a single air-fuel ratio (A/F) sensor is presented. First, a control-oriented engine model is developed that is applicable for arbitrary engine types. With the model, a controller is designed, and the corresponding multirate control system is investigated in terms of stability using eigenvalue analysis. Moreover, a robustness analysis with respect to parametric uncertainties in the phase information is conducted using Monte Carlo simulations. It turns out that a good match of the model at steady state is more important than a sophisticated controller design. The domain of stable operation is identified. A five-cylinder test-bench engine is used to validate the model, to investigate the controller performance during a driving cycle, and to validate the results from the robustness analysis.
Keywords :
Fourier analysis; Fourier transforms; Monte Carlo methods; control system analysis; control system synthesis; eigenvalues and eigenfunctions; engines; fuel systems; stability; Fourier analysis; Monte Carlo simulation; air-fuel ratio sensor; control-oriented engine model; controller design; controller performance; cylinder imbalance control problem; driving cycle; eigenvalue analysis; five-cylinder test-bench engine; individual cylinder air-fuel ratio control; multirate control system; parametric uncertainty; robustness analysis; stability; stable operation; Engines; Fourier transforms; Mathematical model; Robustness; Stability analysis; Air–fuel (A/F) ratio; Fourier transforms; individual cylinder control;
Journal_Title :
Control Systems Technology, IEEE Transactions on
DOI :
10.1109/TCST.2010.2079934
