Dynamic torque management techniques for enhanced engine cycle efficiency

The invention claimed is: 1. A method of operating an integrated circuit-based electronic control system (ECS) to control an engine to propel a vehicle, the method comprising: receiving a throttle command with the ECS; determining with the ECS an operation to increase engine cycle efficiency by reducing engine torque below a magnitude corresponding to the throttle command and below a torque curve limit over a first vehicle operation segment and permitting an increase in the engine torque above the torque curve limit over a second vehicle operation segment; controlling the engine to output torque below the magnitude corresponding to the throttle command and below the torque curve limit over the first vehicle operation segment, said controlling being performed for the throttle command being in response to a driver input and for the throttle command being in response to a signal from a cruise control system implemented in the ECS; and controlling the engine to output torque above the torque curve limit over the second vehicle operation segment in response to a second throttle command received by the ECS and constrained by an extended limit on operation of the engine above the torque curve limit. 2. The method according to claim 1 wherein the first vehicle operation segment and the second vehicle operation segment are defined in units of time. 3. The method according to claim 1 wherein the determining with the ECS the operation to increase engine cycle efficiency utilizes look-ahead information including at least one of a predicted road grade and a predicted vehicle speed. 4. The method according to claim 3 wherein the reducing the engine torque below the magnitude corresponding to the throttle command and below the torque curve limit over the first vehicle operation segment comprises: determining a feedforward torque using the predicted road grade and a cruise control reference speed, determining a feedback torque using the cruise control reference speed and a current vehicle speed, determining a torque limit using the feedforward torque and the feedback torque, and using the torque limit to limit the engine torque below the magnitude corresponding to the throttle command and below the torque curve limit. 5. The method according to claim 3 wherein the reducing the engine torque below the magnitude corresponding to the throttle command and below the torque curve limit over the first vehicle operation segment comprises: determining a feedforward torque using the predicted road grade and the predicted vehicle speed, determining a feedback torque using the predicted vehicle speed and a current vehicle speed, determining a torque limit using the feedforward torque and the feedback torque, and using the torque limit to limit the engine torque below the magnitude corresponding to the throttle command and below the torque curve limit. 6. The method according to claim 3 wherein the predicted vehicle speed is determined by: determining a predicted acceleration power demand using a predicted change in operator power demand and a predicted change in road grade power demand, determining a predicted change in vehicle velocity with a physics-based model using the predicted acceleration power demand and information of a vehicle mass and a vehicle velocity, and determining the predicted vehicle speed using the predicted change in vehicle velocity and a current vehicle speed. 7. The method according to claim 6 wherein at least one of a road grade value and vehicle mass value is dynamically modified from an actual measurement or estimate value to vary a fueling limit utilized in the reducing the engine torque. 8. The method according to claim 3 wherein the predicted vehicle speed is determined using an empirically derived relationship between values of accelerator pedal position, current vehicle speed and predicted vehicle speed. 9. The method according to claim 1 wherein a turbocharger is controlled in response to a predicted increase in road grade to increase an oxygen-to-fuel ratio in advance of the predicted increase in road grade. 10. The method according to claim 1 wherein the operation of the ECS is effective to provide increased engine brake thermal efficiency relative to engine brake thermal efficiency resulting from following the throttle command without reducing the engine torque and constraining engine operation with the torque curve limit without permitting the engine torque above the torque curve limit. 11. A system comprising: an engine; and an integrated circuit-based electronic control system (ECS) structured to control the engine, the ECS being structured to: receive a throttle command; determine an operation to increase engine cycle efficiency by reducing engine torque below a magnitude corresponding to the throttle command and below a torque curve limit over a first vehicle operation segment and permitting an increase in the engine torque above the torque curve limit over a second vehicle operation segment; control the engine to output torque below the magnitude corresponding to the throttle command and below the torque curve limit over the first vehicle operation segment; and control the engine to output torque above the torque curve limit over the second vehicle operation segment in response to a second throttle command received by the ECS and constrained by an extended limit on operation of the engine above the torque curve limit; wherein the ECS is structured to control the engine to output torque below the magnitude corresponding to the throttle command and below the torque curve limit over the first vehicle operation segment at least in response to the throttle command resulting from an output of a cruise control system. 12. The system according to claim 11 wherein the first vehicle operation segment and the second vehicle operation segment are defined in units of distance. 13. The system according to claim 11 wherein the ECS is structured to utilize look-ahead information including at least one of a predicted road grade and a predicted vehicle speed to determine the operation to increase engine cycle efficiency. 14. The system according to claim 13 wherein the ECS is structured to reduce the engine torque below the magnitude corresponding to the throttle command and below the torque curve limit over the first vehicle operation segment by: determining a feedforward torque using the predicted road grade and a cruise control reference speed, determining a feedback torque using the cruise control reference speed and a current vehicle speed, determining a torque limit using the feedforward torque and the feedback torque, and using the torque limit to limit the engine torque below the magnitude corresponding to the throttle command and below the torque curve limit. 15. The system according to claim 13 wherein the ECS is structured to reduce the engine torque below the magnitude corresponding to the throttle command and below the torque curve limit over the first vehicle operation segment by: determining a feedforward torque using the predicted road grade and the predicted vehicle speed, determining a feedback torque using the predicted vehicle speed and a current vehicle speed, determining a torque limit using the feedforward torque and the feedback torque, and using the torque limit to limit the engine torque below the magnitude corresponding to the throttle command and below the torque curve limit. 16. The system according to claim 13 wherein the ECS is structured to determine the predicted vehicle speed by: determining a predicted acceleration