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An automatic matching method for engine control parameters is described which can aid efficient development of new engine control systems. In a spark-ignition engine, fuel is fed to a cylinder in proportion to the air mass induced in the cylinder. Air flow meter characteristics and fuel injector characteristics govern fuel control. The control parameters in the electronic controller should be tuned to the physical characteristics of the air flow meter and the fuel injectors during driving. Conventional development of the engine control system requires a lot of experiments for control parameter matching. The new matching method utilizes the deviation of feedback coefficients for stoichiometric combustion. The feedback coefficient reflects errors in control parameters of the air flow meter and fuel injectors. The relationship between the feedback coefficients and control parameters has been derived to provide a way to tune control parameters to their physical characteristics.

An exhaust gas recirculation (EGR) system that recirculates a portion of the exhaust gas back to the intake system is effective in reducing nitrogen oxide (NOx) emissions from diesel engines. However, improved control accuracy over the EGR flow rate is required, because an excessively large flow rate causes emissions of particulate matter (PM) to increase. In recent years, direct injection (DI) diesel engines have also been used on ordinary passenger cars, because their fuel economy is superior to that of indirect injection (IDI) diesel engines. Since DI engines are more sensitive to the EGR flow rate than their IDI counterparts, improving the accuracy of EGR flow rate control has become even more significant. This study concerned an EGR control algorithm based on the results of calculations performed with an engine model capable of representing the dynamic states of the intake and exhaust systems.

The transient performance of an engine generally depends on the volume of wall flow and behavior of fuel in the induction system which is composed of the intake manifold and the intake port. An experimental technique has been developed for estimating these phenomena in a gasoline engine, which employs a meter for measuring the air-fuel mixture ratio. Using this technique we analyzed single point and multipoint injection systems, and determined the differences in the volume of fuel associated with wall flow. The effects of the shape and specifications of fuel supply system components on the volume of wall flow and fuel behavior in these systems were also made estublished.