Abstract: An improved method of assessing the catalyst warm-up rate of a motor vehicle catalytic converter is based on the response rates of fast warm-up exhaust gas sensors located in the exhaust gas upstream and downstream of the catalytic converter. The method essentially measures an oxygen storage characteristic of the catalyst that increases as the catalyst temperature rises to its ideal operating temperature. In one method, a ratio of switching frequency between the upstream and downstream exhaust gas sensors is periodically computed and compared to a threshold during catalyst warm-up. In another method, the response times of the exhaust gas sensors to a known air/fuel ratio transition are detected to form a measure of the oxygen storage characteristic that is compared to a threshold. In each method, the threshold varies as a function of cumulative airflow through the engine to compensate for different engine airflow levels.

Abstract: An improved method of assessing the catalyst warm-up rate of a motor vehicle catalytic converter is based on the response rates of fast warm-up exhaust gas sensors located in the exhaust gas upstream and downstream of the catalytic converter. The method essentially measures an oxygen storage characteristic of the catalyst that increases as the catalyst temperature rises to its ideal operating temperature. In one method, a ratio of switching frequency between the upstream and downstream exhaust gas sensors is periodically computed and compared to a threshold during catalyst warm-up. In another method, the response times of the exhaust gas sensors to a known air/fuel ratio transition are detected to form a measure of the oxygen storage characteristic that is compared to a threshold. In each method, the threshold varies as a function of cumulative airflow through the engine to compensate for different engine airflow levels.

Abstract: A method for controlling regeneration fuel supplied to an internal combustion engine operating with a lean fuel-air mixture during sequential rich mixture regeneration events of a NOx adsorber in which NOx emissions collected by the adsorber are purged to provide optimum emissions control and minimum fuel consumption. The method monitors the exhaust gases flowing out of the adsorber during the regeneration event to detect when fuel-air mixture to the engine is within an excessively lean or rich range. When the sensed exhaust gases contain an excessively lean fuel-air mixture, fuel is increased to the engine. Fuel is decreased when the sensed exhaust gases contain an excessively rich fuel-air mixture. The fuel can be increased or decreased by adjusting the duration or fuel rate of the regeneration event.

Abstract: Automotive internal combustion engine fuel volatility is estimated during cold start operations by stabilizing air admission to the engine and analyzing engine speed over a modeling period following an engine coldstart after engine speed has stabilized and prior to closed-loop engine operation. If engine speed deviates significantly away from an expected engine speed for the current engine intake air and fuel, a fuel volatility deviation is diagnosed. The magnitude of the fuel volatility deviation away from a nominal fuel volatility is determined as a function of the magnitude of the engine speed deviation. A fuel volatility correction value is updated as a function of the engine speed deviation and is applied throughout an ignition cycle, including during the modeling period to compensate for the fuel volatility deviation.