Methods and systems are provided for detecting cylinder air-fuel imbalance. In one example, a method may include adjusting engine operation based on an indication of cylinder air-fuel imbalance. The imbalance may be detected based on output from a second exhaust gas sensor and a plurality of individ
Methods and systems are provided for detecting cylinder air-fuel imbalance. In one example, a method may include adjusting engine operation based on an indication of cylinder air-fuel imbalance. The imbalance may be detected based on output from a second exhaust gas sensor and a plurality of individual cylinder weighting factors, the second sensor located in an exhaust system downstream of a first sensor located in the exhaust system.
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1. A method for an engine, comprising: adjusting engine operation based on an indication of cylinder air-fuel imbalance detected based on at least two regression analyses, the at least two regression analyses including a first regression analysis performed on a first dataset and a second regression
1. A method for an engine, comprising: adjusting engine operation based on an indication of cylinder air-fuel imbalance detected based on at least two regression analyses, the at least two regression analyses including a first regression analysis performed on a first dataset and a second regression analysis performed on a larger, second dataset, and each of the first dataset and the second dataset including output from a second sensor, located in an exhaust system downstream of a first sensor located in the exhaust system, and a plurality of individual cylinder weighting factors each describing a contribution of a respective individual cylinder to an overall air-fuel ratio sensed by the first sensor for a given engine speed and load condition. 2. The method of claim 1, wherein the second sensor is located in the exhaust system downstream of a confluence area where exhaust streams from a plurality of cylinders converge. 3. The method of claim 2, wherein the first sensor is located upstream of the confluence area, and wherein the plurality of individual cylinder weighting factors comprises a weighting factor for each cylinder of the plurality of cylinders for at least one engine speed and load condition. 4. The method of claim 3, wherein, to determine the cylinder air-fuel imbalance, the method comprises, for a first engine speed and load condition: storing the first data set comprising a first downstream air-fuel ratio measured by the second sensor, a corresponding first desired air-fuel ratio for the first sensor, and a first subset of the plurality of individual cylinder weighting factors, the first subset including a weighting factor for each of the plurality of cylinders at the first engine speed and load condition; andperforming the first regression analysis on the first data set to determine a first cylinder air-fuel ratio for each cylinder of the plurality of cylinders. 5. The method of claim 4, wherein, to determine the cylinder air-fuel imbalance, the method further comprises, for a second engine speed and load condition: storing the second data set comprising a second downstream air-fuel ratio measured by the second sensor, a corresponding second desired air-fuel ratio for the first sensor, and a second subset of the plurality of individual cylinder weighting factors, the second subset including a weighting factor for each of the plurality of cylinders at the second engine speed and load condition; andperforming the second regression analysis on the first data set and the second data set to determine a second cylinder air-fuel ratio for each cylinder of the plurality of cylinders. 6. The method of claim 5, further comprising iteratively repeating the storing and performing of a subsequent regression analysis for one or more subsequent engine speed and load conditions until the subsequent regression analysis is indicated to be statistically significant, and indicating that the cylinder air-fuel imbalance is a cylinder air-fuel imbalance for a first cylinder of the plurality of cylinders if a statistically-significant air-fuel ratio for the first cylinder of the plurality of cylinders determined by the statistically-significant regression analysis differs from an average air-fuel ratio by more than a threshold. 7. The method of claim 6, wherein adjusting engine operation comprises adjusting a fuel injection amount supplied to the first cylinder. 8. The method of claim 2, wherein the second sensor is located downstream of a catalyst positioned in an exhaust passage that is in fluidic communication with the engine, and wherein the first sensor is located upstream of the catalyst. 9. The method of claim 3, further comprising learning the plurality of individual cylinder weighting factors during a learning mode of the engine, the learning mode of the engine comprising: for each of a plurality of engine speed and load conditions, purposely varying an air-fuel ratio for each cylinder of the plurality of cylinders and measuring each resultant exhaust air-fuel ratio with the first sensor, anddetermining the plurality of individual cylinder weighting factors based on the resultant exhaust air-fuel ratios for each cylinder at each of the plurality of engine speed and load conditions. 10. The method of claim 1, wherein adjusting engine operation comprises one or more of adjusting an engine torque limit, lowering boost pressure, adjusting fuel injection timing, and reducing spark retard. 11. The method of claim 1, wherein the indication of cylinder air-fuel imbalance is further based on a desired air-fuel ratio at the first sensor. 12. A method for an engine, comprising: adjusting engine operation based on an indication of cylinder air-fuel imbalance detected based on at least two regression analyses including a first regression analysis and a second regression analysis each performed on respective first and second datasets including a plurality of measured post-catalyst air-fuel ratios, a plurality of corresponding desired pre-catalyst air-fuel ratios, and a plurality of individual cylinder weighting factors each describing a contribution of a respective individual cylinder to an overall air-fuel ratio sensed at a pre-catalyst location for a given engine speed and load condition, wherein the second dataset includes the first dataset, and wherein the second dataset is larger than the first dataset. 13. The method of claim 12, where adjusting engine operation includes increasing an amount of fuel delivered to a cylinder associated with the cylinder air-fuel imbalance when the cylinder air-fuel imbalance indicates a lean imbalance. 14. The method of claim 12, where adjusting engine operation includes decreasing an amount of fuel delivered to a cylinder associated with the cylinder air-fuel imbalance when the cylinder air-fuel imbalance indicates a rich imbalance. 15. The method of claim 5, further comprising indicating the cylinder air-fuel imbalance if at least one of the second cylinder air-fuel ratios differs from an average air-fuel ratio by more than a threshold.
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이 특허에 인용된 특허 (19)
Hasegawa Yusuke (Saitama JPX) Maki Hidetaka (Saitama JPX), A/F ratio estimator for multicylinder internal combustion engine.
Suzuki, Yusuke; Iwazaki, Yasushi; Kidokoro, Toru; Sawada, Hiroshi; Nakamura, Fumihiko; Aoki, Keiichiro, Air-fuel ratio control apparatus and method for an internal combustion engine.
Remboski Donald J. (Northborough MA) Plee Steven L. (Northborough MA) Yang Jialin (Westboro MA) Law Robert W. (Acton MA) Vincent Michael T. (Grafton MA), Method and apparatus for operating an engine.
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