Systems and methods are described for coordinating the regeneration of a gasoline particulate filter to a time duration when engine output falls below a predetermined load threshold selected to indicate a low power state of the engine. In one particular example, the engine is configured to adjust en
Systems and methods are described for coordinating the regeneration of a gasoline particulate filter to a time duration when engine output falls below a predetermined load threshold selected to indicate a low power state of the engine. In one particular example, the engine is configured to adjust engine operations to regenerate the particulate filter responsive to engine output falling below a predetermined low power threshold, the regeneration further based on an estimated duration that the output falls continuously below the low power threshold. The system and methods described advantageously allow for either full or partial regeneration events to be performed based on the estimated duration of the engine output below the low power threshold.
대표청구항▼
1. A method for regenerating a particulate filter, comprising: predicting a series of impending periods of engine operation during each of which engine output is predicted to be continuously below a predetermined low power threshold for an estimated duration below a predetermined time threshold, the
1. A method for regenerating a particulate filter, comprising: predicting a series of impending periods of engine operation during each of which engine output is predicted to be continuously below a predetermined low power threshold for an estimated duration below a predetermined time threshold, the impending periods separated by intervening periods during which engine output exceeds the low power threshold;adjusting engine operation to perform a series of partial regenerations of the particulate filter, including partial regeneration of the particulate filter during each impending period, where an extent of each partial regeneration is based on the estimated duration of the impending period during which it is performed. 2. The method of claim 1, further comprising processing information from a cloud navigation system, wherein the prediction of the series of impending periods and the estimation of the duration of the impending periods are further based on information from the cloud navigation system. 3. The method of claim 2, wherein the prediction of the series of impending periods is performed responsive to a soot load of the particulate filter exceeding a threshold. 4. The method of claim 1, wherein adjusting engine operation to perform the series of partial regenerations of the particulate filter includes decreasing an amount of fuel injected to a cylinder of the engine. 5. The method of claim 4, wherein adjusting engine operation to perform the series of partial regenerations of the particulate filter further includes increasing an amount of fuel injected to one or more remaining cylinders of the engine responsive to the decrease in the amount of fuel injected to the cylinder, the engine output being maintained during the particulate filter regeneration. 6. The method of claim 5, wherein adjusting engine operation to perform the series of partial regenerations of the particulate filter further includes adjusting a rate of regeneration of the particulate filter by controlling a level of fuel injected to the cylinder of the engine to adjust a flow of oxygen to the particulate filter. 7. The method of claim 1, wherein the estimated durations of the impending periods are based on an output trend of the engine. 8. The method of claim 1, further comprising suspending the particulate filter regeneration responsive to the engine output rising above the low power threshold during the regeneration, wherein suspending the regeneration includes readjusting engine operation to provide engine power based on a power demand. 9. An engine system, comprising: at least two cylinders configured with a fuel injector communicatively attached to each cylinder,a gasoline particulate filter (GPF), anda controller including instructions stored in non-transitory memory to process one or more of cloud data and an engine output trend to estimate a plurality of time durations, each estimated time duration corresponding to an impending period of engine operation during which engine power output is predicted to be continuously below a predetermined low power threshold, and each of the impending periods being separated by intervening periods of engine operation during which engine power output is predicted to exceed the low power threshold, the controller further comprising instructions stored in non-transitory memory to, in response to all of the estimated time durations being below a predetermined time threshold, adjust engine operation to perform a series of partial GPF regenerations, each partial GPF regeneration performed during one of the impending periods, wherein an extent of each partial GPF regeneration is based on the estimated time duration corresponding to the impending period during which it is performed, and wherein the series of partial GPF regenerations coordinately perform a full GPF regeneration. 10. The engine system of claim 9, wherein the controller further comprises instructions stored in non-transitory memory to adjust engine operation to perform a full GPF regeneration during an impending period of engine operation when the estimated time duration corresponding to the impending period is above a predetermined time threshold. 11. The engine system of claim 10, wherein the controller further comprises instructions stored in non-transitory memory to decrease an amount of fuel injected to a cylinder to regenerate the GPF while increasing an amount of fuel injected to one or more remaining cylinders to maintain the engine output during the regeneration. 12. The engine system of claim 11, wherein during each impending period, the controller further comprises instructions stored in non-transitory memory to control the amount of fuel injected to the cylinder to adjust a rate of GPF regeneration, an extent of fuel injection allowing for adjusting the rate of GPF regeneration by adjusting a flow of oxygen to an engine exhaust based on the estimated time duration corresponding to the impending period. 13. The engine system of claim 12, wherein the controller further comprises instructions stored in non-transitory memory to control the amount of fuel injected to the one or more remaining cylinders to maintain engine output during each impending period based on the estimated time duration corresponding to the impending period. 14. A method for regenerating a gasoline particulate filter (GPF), comprising: processing cloud data to predict a series of impending periods of engine operation during each of which engine output is continuously below a predetermined low power threshold for an estimated duration below a predetermined time threshold, the impending periods being separated by intervening periods of engine operation during which engine output is predicted to exceed the low power threshold; andadjusting engine operation to perform a series of partial GPF regenerations, including adjusting engine operation to perform a partial GPF regeneration of the particulate filter during each impending period, where an extent of each partial GPF regeneration is based on the estimated duration of the impending period during which it is performed.
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