Methods and systems for individual cylinder air-fuel ratio control in a combustion engine

The invention claimed is: 1. An engine system, comprising: a first bank of combustion cylinders, each of the combustion cylinders of the first bank exhaustively coupled by way of a separate cylinder exhaust runner to a first exhaust manifold; a first high-frequency exhaust gas composition sensor fluidly coupled to the first exhaust manifold; and a controller, including executable instructions thereon to, measure a high-frequency exhaust gas composition at the first high-frequency exhaust gas composition sensor, and for a first combustion cylinder of the first bank, parse the measured high-frequency exhaust gas composition to determine a first combustion cylinder-specific component of the high-frequency exhaust gas composition; estimate an air-fuel ratio (AFR) based on the first combustion cylinder-specific component of the measured high-frequency exhaust gas composition; and correct the estimated AFR by removing intercylinder exhaust gas interactions from the estimated AFR. 2. The engine system of claim 1 , further comprising: a second bank of combustion cylinders, each of the combustion cylinders of the second bank exhaustively coupled by way of a separate cylinder exhaust runner to a second exhaust manifold; a second high-frequency exhaust gas composition sensor fluidly coupled to the second exhaust manifold; and a controller, including executable instructions thereon to, measure a high-frequency exhaust gas composition at the second high-frequency exhaust gas composition sensor, and for a first combustion cylinder of the second bank, parse the measured high-frequency exhaust gas composition to determine a first combustion cylinder-specific component of the high-frequency exhaust gas composition; estimate an air-fuel ratio (AFR) based on the first combustion cylinder-specific component of the measured high-frequency exhaust gas composition; and correct the estimated AFR by removing intercylinder exhaust gas interactions from the estimated AFR. 3. The engine system of claim 1 , wherein the first high-frequency exhaust gas composition sensors is positioned downstream from the separate cylinder exhaust runners, and upstream of an emission control device. 4. The engine system of claim 3 , wherein the executable instructions to measure the high-frequency exhaust gas composition include measuring the high-frequency exhaust gas composition comprises measuring an exhaust gas composition below a threshold sampling rate. 5. A method for an engine, comprising: measuring a high-frequency exhaust gas composition, and for a first cylinder of the engine, parsing the measured high-frequency exhaust gas composition to determine a first cylinder-specific component of the high-frequency exhaust gas composition; estimating an air-fuel ratio (AFR) based on the first cylinder-specific component of the measured high-frequency exhaust gas composition; and correcting the estimated AFR by subtracting intercylinder exhaust gas interactions from the estimated AFR. 6. The method of claim 5 , wherein measuring the high-frequency exhaust gas composition comprises measuring the high-frequency exhaust gas composition for a threshold duration. 7. The method of claim 5 , wherein the first cylinder-specific component comprises a portion of the measured high-frequency exhaust gas composition derived from exhaust gas expelled from the first cylinder. 8. The method of claim 5 , wherein the intercylinder exhaust gas interactions comprise contributions to the measured high-frequency exhaust gas composition signal from cylinders other than the first cylinder. 9. The method of claim 5 , further comprising, for each cylinder of the engine, estimating an AFR based on a cylinder-specific component of the measured high-frequency exhaust gas composition; and correcting the estimated AFR by subtracting intercylinder exhaust gas interactions from the estimated AFRs. 10. The method of claim 5 , further comprising, for the first cylinder, calculating an AFR correction factor based on the deviation of the corrected estimated AFR from a target AFR, and applying the AFR correction factor to feedback control of the AFR to reduce deviation of the AFR from the target AFR. 11. The method of claim 10 , further comprising, for the first cylinder, storing the calculated AFR correction factor, and applying the AFR correction factor to feedforward control of the AFR to reduce deviation of the AFR from the target AFR. 12. The method of claim 11 , further comprising, for the first cylinder, determining the first cylinder is faulty when a deviation between the stored calculated AFR correction factor and a predetermined AFR correction factor is greater than a threshold deviation. 13. A method of estimating air-fuel ratio in individual engine cylinders, comprising: measuring an exhaust gas composition at a measurement frequency above a threshold frequency, and for exhaust gas composition data measured over a threshold period, resolving the measured exhaust gas composition data into cylinder-specific components, estimating an air-fuel ratio (AFR) of each individual engine cylinder based on the resolved cylinder-specific components, and correcting the estimated AFR of each individual engine cylinder, including applying an interaction matrix of binary interaction parameters to remove intercylinder exhaust gas interaction contributions from the estimated AFR of each individual engine cylinder. 14. The method of claim 13 , wherein the threshold period comprises one firing cycle for a bank of engine cylinders corresponding to the individual engine cylinders. 15. The method of claim of claim 13 , wherein resolving the measured exhaust gas composition data measured over the threshold period into engine cylinder-specific components comprises dividing the data into sequential time intervals corresponding to the firing sequence of the individual engine cylinders, and assigning the measured exhaust composition data over each of the sequential time interval to the corresponding engine cylinder. 16. The method of claim 13 , wherein resolving the measured exhaust gas composition data measured over the threshold period into engine cylinder-specific components comprises dividing the data into sequential event intervals corresponding to the firing sequence of the individual engine cylinders, and assigning the measured exhaust composition data over each event interval to the corresponding engine cylinder. 17. The method of claim 16 , wherein each sequential event interval comprises a pulse of the of exhaust composition data above a threshold amplitude. 18. The method of claim 13 , wherein applying the interaction matrix includes applying the interaction matrix, wherein the interaction matrix comprises i×j binary interaction parameters, i and j varying from 1 to n, n being a number of individual engine cylinders, and each of the ij th binary interaction parameters quantifying a binary exhaust gas composition interaction induced by the exhaust gas expelled from the i th engine cylinder on the exhaust gas expelled from the j th engine cylinder. 19. The method of claim 18 , wherein removing the intercylinder exhaust gas interaction contributions from the estimated AFR of each j=k th engine cylinder includes applying each ik th binary interaction parameter to the estimated AFR of the k th engine cylinder. 20. The method of claim 19 , wherein applying the interaction matrix includes applying the ij th binary interaction parameter corresponding to a current engine