Diesel engine steady state and transient hybrid optimization

The invention claimed is: 1. Method for selecting an engine operating point in a multi-mode powertrain system employing a diesel engine and one or more non-combustion torque machines arranged to transfer torque to a driveline via a transmission device, the method comprising: monitoring a desired axle torque based on an operator torque request and vehicle speed; monitoring availability of a plurality of combustion modes of the diesel engine; for each available combustion mode: receiving an engine torque range from a minimum engine torque to a maximum engine torque, receiving an engine speed range from a minimum engine speed to a maximum engine speed, retrieving a plurality of fuel losses, each fuel loss corresponding to respective ones of a plurality of engine operating points within the engine torque and speed ranges, retrieving a plurality of emissions losses, each emissions loss corresponding to respective ones of the plurality of engine operating points within the engine torque and speed ranges, and at each of a plurality of potential engine operating points within the engine torque and speed ranges of the available combustion modes, comparing the respective fuel and emissions losses; selecting a desired engine operating point within one of the available combustion modes, the desired engine operating point corresponding to one of the potential engine operating points having a lowest power loss based on the compared respective fuel and emissions losses; and controlling the diesel engine to said desired engine operating points by controlling actuators to control combustion parameters in said one of the available combustion modes. 2. The method of claim 1 , wherein each of the plurality of potential engine operating points within the engine torque and speed ranges of the available combustion modes are utilized to achieve the desired axle torque. 3. The method of claim 2 , further comprising: for each respective potential engine operating point that does not achieve the desired axle torque, assigning a respective motor torque from the one or more electric machines to achieve the desired axle torque when combined with the respective potential engine operating point. 4. The method of claim 2 , wherein each of the plurality of potential engine operating points correspond to respective ones of a plurality of gear ratios of the transmission device, each potential engine operating point utilized to achieve the desired axle torque when multiplied by one of the plurality of gear ratios of the transmission device. 5. The method of claim 1 , wherein comparing the respective fuel and emissions losses comprises: summing the respective fuel and emissions losses; and determining a respective power loss based on the summing. 6. The method of claim 5 , further comprising: at each of the plurality of potential engine operating points: determining a respective energy loss based on electrical power required to supply the one or more torque machines providing motor torque, wherein the respective power loss is further based on the respective energy loss. 7. The method of claim 5 , further comprising: at each of the plurality of potential engine operating points: determining a respective transmission spin loss based on a selected gear ratio of the transmission, wherein the respective power loss is further based on the respective transmission spin loss. 8. The method of claim 1 , further comprising: determining an injected fuel mass to achieve the desired engine operating point; and adjusting intake air mass to achieve a desired air-fuel ratio at the desired engine operating point based on the determined injected fuel mass. 9. The method of claim 8 , wherein adjusting the intake air mass to achieve the desired air-fuel ratio comprises: adjusting at least one of exhaust gas recirculation entering the diesel engine, intake air pressure and throttle opening to achieve the desired air-fuel at the desired engine operating point within the one of the available combustion modes based on the determined injected fuel mass. 10. The method of claim 8 , wherein the desired air-fuel ratio at the desired engine operating point is based on a desired balance of emissions efficiency, fuel efficiency, noise, vibrations and harshness. 11. The method of claim 1 , further comprising: if a transient in the desired engine operating point is determined, monitoring a desired instantaneous air-fuel ratio corresponding to the desired engine operating point; estimating an instantaneous intake air mass; determining a desired instantaneous injected fuel mass to achieve the desired instantaneous air-fuel ratio based on the estimated instantaneous intake air mass; and translating the desired instantaneous injected fuel mass to a desired torque request. 12. The method of claim 11 , further comprising: monitoring motor torque capacity; determining an immediate torque request to achieve the desired axle torque based on the monitored motor torque capacity and the desired torque request, wherein the immediate torque request corresponds to the desired torque request when the motor torque capacity is sufficient for achieving the desired axle torque when combined with the desired torque request. 13. The method of claim 12 , further comprising: a third combustion mode comprising an engine torque and speed range decreased from operation in the first combustion mode and increased from operation in the second combustion mode, emissions losses decreased from operation in the first combustion mode and increased from operation in the second combustion mode, fuel losses increased from operation in the first combustion mode and decreased from operation in the second combustion mode, and drivability decreased from operation in the first combustion mode and increased from operation in the second combustion mode. 14. The method of claim 11 , wherein the desired instantaneous air-fuel ratio always remains below a smoke limit of the diesel engine. 15. The method of claim 1 , wherein the plurality of combustion modes comprise: a first combustion mode that is always available; and a second combustion mode comprising a decreased engine torque and speed range, decreased emissions losses, increased fuel losses and decreased drivability from operation in the first combustion mode. 16. The method of claim 15 , wherein the second combustion mode is not available when a fault conditions exits, the fault condition comprising at least one of: a fault in in-cylinder pressure; a fault in air control to the engine; and environmental conditions indicating that operation in the second combustion mode is not desirable. 17. The method of claim 1 , wherein the retrieved plurality of emissions losses correspond to magnitudes of at least one of nitrous oxide and hydrocarbons, wherein higher emissions losses are indicative of higher magnitudes of nitrous oxide and hydrocarbons. 18. Method for selecting a desired engine torque in a multi-mode powertrain system employing a diesel engine and one or more electric machines arranged to transfer torque to a driveline via a transmission device, the method comprising: monitoring a desired axle torque based on an operator torque request and a present vehicle speed; monitoring availability of at least two combustion modes of the diesel engine, one of the combustion modes having a higher emissions efficiency than the other one or more combustion modes; for each available combustion mode: receiving engine torque and speed ranges; retrieving a pluralit