Abstract: Methods and systems are provided for addressing cylinder-to-cylinder imbalances in the incidence of pre-ignition and/or knock. Engine cylinders are fueled based on each cylinder's pre-ignition count to balance the incidence of pre-ignition in each cylinder. The fueling is adjusted to maintain engine exhaust at stoichiometry.

Abstract: Methods and systems are provided for mitigating engine pre-ignition based on a feed-forward likelihood of pre-ignition and feedback from a pre-ignition event. In response to an indication of pre-ignition, a cylinder may be enriched while an engine load is limited. The enrichment may be followed by an enleanment to restore exhaust catalyst feed-gas oxygen levels. The mitigating steps may be adjusted based on engine operating conditions, a pre-ignition count, as well as the nature of the pre-ignition.

Abstract: Methods and systems are provided for mitigating engine pre-ignition based on a feed-forward likelihood of pre-ignition and feedback from a pre-ignition event. In response to an indication of pre-ignition, a cylinder may be enriched while an engine load is limited. The enrichment may be followed by an enleanment to restore exhaust catalyst feed-gas oxygen levels. The mitigating steps may be adjusted based on engine operating conditions, a pre-ignition count, as well as the nature of the pre-ignition.

Abstract: A method for controlling spark timing. A plurality of tables provides borderline timing data contributors for each of a corresponding one of a plurality of different engine operating conditions. The contributors in each table are a function of engine speed and air charge. Background borderline spark timing is determined at a background computational rate from a summation of the borderline timing data in the plurality of tables data in the plurality of tables at engine speed measured at the borderline computational rate and air charge determined at the borderline computational rate. A one-dimensional table has borderline timing data contributors extracted from the provided tables. The extracted borderline timing data contributors are the engine sped measured at the borderline computational rate and the air charge determined at the borderline computational rate. From the one-dimensional table, foreground borderline spark timing is determined at a higher, foreground computational rate.

Abstract: A method for controlling spark timing. A plurality of tables provides borderline timing data contributors for each of a corresponding one of a plurality of different engine operating conditions. The contributors in each table are a function of engine speed and air charge. Background borderline spark timing is determined at a background computational rate from a summation of the borderline timing data in the plurality of tables data in the plurality of tables at engine speed measured at the borderline computational rate and air charge determined at the borderline computational rate. A one-dimensional table has borderline timing data contributors extracted from the provided tables. The extracted borderline timing data contributors are the engine speed measured at the borderline computational rate and the air charge determined at the borderline computational rate. From the one-dimensional table, foreground borderline spark timing is determined at a higher, foreground computational rate.

Abstract: A method and system for estimating the midbed temperature of a catalytic converter in an exhaust system of an internal combustion engine. A rate of change in the speed of the engine is sensed and an estimated number of misfires occurring in the engine over a predetermined number of cylinder filling events is determined based on the sensed rate of change in engine speed. An instantaneous temperature of exhaust gas at the exhaust flange is determined based on the estimated rate of misfires. An instantaneous temperature at the midbed point of the catalytic converter is then determined based on the instantaneous temperature of exhaust gas at the exhaust flange. The instantaneous temperature at the midbed point is compared to a predetermined temperature threshold and the estimate rate of misfires is compared to a predetermined misfire rate threshold.