Engine torque smoothing

The invention claimed is: 1. A control system configured to control the transition of an engine between different firing fractions in a hybrid vehicle having an internal combustion engine and an additional power source/sink, the control system comprising: an engine control unit configured to direct operation of the engine, including directing the transition of the engine from a first operational firing fraction to a target firing fraction that is different than the first operational firing fraction, and determining a firing sequence that facilitates the transition between the first operational firing fraction and the target firing fraction; a torque profile estimator configured to determine an engine torque profile associated with the firing sequence; and an additional power source/sink controller configured to determine a smoothing torque based at least in part of the determined engine torque profile and to direct the additional power source/sink to apply the smoothing torque during the transition from the first operational firing fraction. 2. A control system as recited in claim 1 wherein the smoothing torque is arranged to cause a predicted net powertrain torque to not exceed a threshold instantaneous torque throughout the transition. 3. A control system as recited in claim 1 wherein the smoothing torque is a filtered version of the torque profile. 4. A method of controlling the transition of an engine between different firing fractions in a hybrid vehicle having an internal combustion engine and an additional power source/sink, the method comprising: while the engine is operating at a first firing fraction, determining a second target firing fraction that is different than the first firing fraction; determining a firing sequence to transition between the first firing fraction and the second firing fraction; determining an engine torque profile associated with the firing sequence; determining a smoothing torque based at least in part of the determined engine torque profile; and during the transition from the first firing fraction to the second target firing fraction applying the smoothing torque using the additional power source/sink. 5. A method as recited in claim 4 wherein the smoothing torque is arranged to cause a predicted net powertrain torque to not exceed a threshold instantaneous torque throughout the transition. 6. A method as recited in claim 4 wherein the smoothing torque is a filtered version of the torque profile. 7. A control system for controlling a powerplant including an engine having a crankshaft and an accessory selected from the group consisting of an alternator and an air conditioner compressor, the control system comprising: an engine control unit configured to direct operation of the engine in a dynamic firing level modulation mode; a torque profile modeling module configured to determine an expected torque profile associated with a sequence of one or more firing opportunities; and an additional power source/sink controller configured to control the accessory to directly or indirectly apply a varying load on the crankshaft based at least in part on the expected torque profile. 8. A control system as recited in claim 7 wherein the additional power source/sink controller is configured to apply the varying load in a manner that reduces a magnitude of driveline vibration. 9. A control system as recited in claim 7 wherein the additional power source/sink controller is configured to synchronized the varying load with the variations in the expected torque profile over the course of an engine cycle in a manner that reduced net torque variations applied to a drive train by a combination of the engine and the accessory over the course of the engine cycle during operation in the dynamic firing level modulation mode. 10. A control system as recited in claim 9 wherein the varying load is arranged to cause a predicted net powertrain torque applied by the engine and the accessory to not exceed a threshold instantaneous torque. 11. A method of controlling a powerplant including an engine having a crankshaft and an accessory selected from the group consisting of an alternator and an air conditioner compressor, the method comprising: operating an engine in a dynamic firing level modulation mode; determining an expected torque profile associated with a sequence of one or more firing opportunities; and controlling the accessory to directly or indirectly apply a varying load on the crankshaft based at least in part on the expected torque profile. 12. A method as recited in claim 11 wherein the varying load is applied in a manner that reduces a magnitude of driveline vibration. 13. A method as recited in claim 11 wherein the varying load is synchronized with the variations in the expected torque profile over the course of an engine cycle in a manner that reduced net torque variations applied to a drive train by a combination of the engine and the accessory over the course of the engine cycle during operation in the dynamic firing level modulation mode. 14. A method as recited in claim 13 wherein the varying load is arranged to cause a predicted net powertrain torque applied by the engine and the accessory to not exceed a threshold instantaneous torque.