Method to select optimal mode on a multi-mode engine with charging

What is claimed is: 1. A control method for selecting an optimal multiple-step operating mode for a motor vehicle engine system, comprising: providing at least two variable capacity modes of operation, the at least two variable capacity modes of operation including modes combining variable valve lift per cylinder and modes defining cylinder deactivation; prioritizing the at least two variable capacity modes based on fuel efficiency by ranking the at least two variable capacity modes from a mode having a lowest predicted fuel flow to a mode having a highest predicted fuel flow; applying torque constraint data and noise and vibration (NV) constraint data to the prioritized variable capacity modes; and conducting a mode determination arbitration for the prioritized variable capacity modes having the torque constraint and the vibration constraint data applied to select the mode with the lowest predicted fuel flow allowed by the torque constraint data and the NV constraint data. 2. The control method for selecting an optimal multiple step operating mode for a motor vehicle engine system of claim 1 , wherein the at least two variable capacity modes include a first mode defining a full torque capacity (FTC) mode having all cylinders operating at high lift, a second mode defining a first reduced capacity economy mode (RCE1) having all cylinders operating at low lift, and a third mode defining a second reduced capacity economy mode (RCE2) having fewer than all of the cylinders operating. 3. The control method for selecting an optimal multiple step operating mode for a motor vehicle engine system of claim 2 , including: evaluating a first engine speed (rpm) signal and a first desired torque signal in conjunction with full torque capacity data in a first FTC lookup table; analyzing a second engine speed (rpm) signal and a second desired torque signal in conjunction with first reduced capacity economy data in a second RCE1 lookup table; and assessing a third engine speed (rpm) signal and a third desired torque signal in conjunction with second reduced capacity economy data in a third RCE2 lookup table. 4. The control method for selecting an optimal multiple step operating mode for a motor vehicle engine system of claim 3 , including generating each of a predicted FTC fuel flow signal, a predicted RCE1 fuel flow signal, and a predicted RCE2 fuel flow signal. 5. The control method for selecting an optimal multiple step operating mode for a motor vehicle engine system of claim 4 , wherein ranking the at least two variable capacity modes includes sorting in a sorting module the predicted FTC fuel flow signal, the predicted RCE1 fuel flow signal, and the predicted RCE2 fuel flow signal between a lowest predicted fuel flow, a next or second lowest predicted fuel flow, and a highest predicted fuel flow. 6. The control method for selecting an optimal multiple step operating mode for a motor vehicle engine system of claim 5 , including forwarding the lowest predicted fuel flow, the second lowest predicted fuel flow, and the highest predicted fuel flow to each of an allowable mode evaluator and an arbitration module. 7. The control method for selecting an optimal multiple step operating mode for a motor vehicle engine system of claim 6 , including determining if FTC mode is allowed or not allowed, if RCE1 mode is allowed or not allowed, and if RCE2 mode is allowed or not allowed. 8. The control method for selecting an optimal multiple step operating mode for a motor vehicle engine system of claim 7 , including prior to the conducting step transmitting the mode that is ranked having the lowest fuel consumption that is allowed from the allowable mode evaluator to each of an arbitration module and a mode determination module. 9. The control method for selecting an optimal multiple step operating mode for a motor vehicle engine system of claim 3 , wherein an engine speed represented by the first engine speed (rpm) signal and an engine speed represented by the second engine speed (rpm) signal are substantially the same, and wherein the engine speed represented by the third engine speed (rpm) signal is greater than the first and the second engine speed signals due to torque converter slip. 10. The control method for selecting an optimal multiple step operating mode for a motor vehicle engine system of claim 1 , wherein the applying step includes incorporating boost by calculating a maximum torque capacity for each of the modes that is a function of a current boost pressure. 11. The control method for selecting an optimal multiple step operating mode for a motor vehicle engine system of claim 1 , wherein the at least two variable capacity modes include a first mode having a highest torque capacity with a lowest fuel efficiency, a second mode having a medium torque capacity less than the highest torque capacity and with a medium fuel efficiency higher than the lowest fuel efficiency, and a third mode having a lowest torque capacity lower than the medium torque capacity and with a highest fuel efficiency higher than the medium fuel efficiency. 12. The control method for selecting an optimal multiple step operating mode for a motor vehicle engine system of claim 1 , wherein the at least two variable capacity modes include a first mode, a second mode, a third mode, and a fourth mode, wherein the first mode includes a highest lift, the second mode includes a high lift having a lift lower than the highest lift, the third mode includes a medium a lift lower than the high lift, and the fourth mode includes a low lift lower than the medium lift. 13. A control method for selecting an optimal multiple step operating mode for a multiple cylinder motor vehicle engine system having variable lift, comprising: prioritizing each of a full torque capacity (FTC) mode having all cylinders operating at high lift, a first reduced capacity economy mode (RCE1) having all cylinders operating at low lift, and a second reduced capacity economy mode (RCE2) having fewer than all of the cylinders operating at low lift with at least one cylinder deactivated based on predicted fuel economy of each of the modes; sorting the prioritized modes between mode having a lowest predicted fuel flow, a mode having a next or second lowest predicted fuel flow, and a mode having a highest predicted fuel flow; applying multiple constraints to each of the prioritized modes including incorporating boost as one of the constraints by calculating a maximum torque capacity for each of the modes that is a function of a current boost pressure; and conducting a mode determination arbitration to identify if a change in mode is required. 14. The control method for selecting an optimal multiple step operating mode for a multiple cylinder motor vehicle engine system having variable lift of claim 13 , including determining the current boost pressure by measuring a total throttle inlet air pressure (TIAP) indicative of the current boost pressure. 15. The control method for selecting an optimal multiple step operating mode for a multiple cylinder motor vehicle engine system having variable lift of claim 14 , including: entering each of a torque request and a filtered torque request; and applying an offset to the maximum torque capacity for each of the modes. 16. The control method for selecting an optimal multiple step operating mode for a multiple cylinder motor vehicle engine system having variable lift of claim 15 , including comparing the filtered torque request to the maximum torque capacity plus the offset during the conducting step. 17. The control method for s