HEV engine start vibration reduction system

What is claimed is: 1. A vehicle comprising: an electronic continuously variable transmission coupled to an engine, electric machine, and at least one controller configured to, at discrete time intervals during engine start: adjust torque of the electric machine to reduce startup vibration of the engine with a feedforward torque signal generated from an engine start profile produced with a blend factor generated as a difference between an engine operating condition and stored operating condition grids. 2. A vehicle comprising: an engine; an electric machine; a continuously variable transmission coupled to the engine and the electric machine; and a controller coupled to the engine, the electric machine, and the continuously variable transmission, the controller configured to adjust torque of the electric machine to reduce startup vibration of the engine using a feedforward torque signal generated from an engine start profile produced with a blend factor corresponding to a difference between an engine operation condition and stored operating condition grids, wherein the controller is further configured to: select a nearest operating condition grid from the stored operating condition grids according to a current engine operating condition, select from the stored operating condition grids one of: (a) an historical operating condition, and (b) a nearest neighbor operating condition grid when no historic operating condition grid exists, and generate the blend factor as the difference being a smallest of a distance between the current engine operating condition, and each of the nearest operating condition and the one of the historical operating condition grid and the nearest neighbor operating condition grid, calibrate the start profile with the blend factor and the NOCG and the one of the HOCG and NNOCG, and generate an engine cranking torque and the feedforward torque signal from the calibrated start profile. 3. The vehicle according to claim 2 , further comprising: the at least one controller further configured to: select the NOCG and NNOCG from the SOCGs in a database of predetermined baseline OC grids, and the HOCG from an historical database of SOCGs of prior engine starts. 4. The vehicle according to claim 2 , further comprising: the at least one controller further configured to: generate a cranking torque compensation factor according to a mechanical damper model of the transmission, calibrate the engine cranking torque with the compensation factor, and adjust a gear ratio of the transmission according to the calibrated start profile and the calibrated engine cranking torque. 5. The vehicle according to claim 2 , further comprising: an engine start OC and noise and vibration recorder; and the at least one controller coupled with the recorder and further configured to: generate and store with the recorder in a database of HOCGs, new HOCGs for each engine start that includes a minimum noise and vibration metric (MNVM). 6. A method for controlling a vehicle, comprising: by a controller coupled to an electronic continuously variable transmission, an engine, and an electric machine: adjusting at discrete time intervals during starting of the engine, a torque of the electric machine using a feedforward torque signal generated from an engine start profile produced with a blend factor generated as a difference between an engine operating condition and stored operating condition grids, including: selecting a nearest operating condition grid from the stored operating condition grids according to a current engine operating condition, selecting from the stored operating condition grids one of: (a) an historical operating condition grid, and (b) a nearest neighbor operating condition grid when no historical operating condition grid exists, generating the blend factor as the difference being a smallest of a distance between the current engine operating condition and each of the nearest operating condition grid and the selected one of the historical operating condition grid and the nearest neighbor operating condition grid, calibrating the start profile with the blend factor and the nearest operating condition grid and the selected one of the historical operating condition grid and the nearest neighbor operating condition grid, and generating an engine cranking torque and the feedforward torque signal from the calibrated start profile. 7. The method for controlling a vehicle according to claim 6 , further comprising: by the at least one controller: selecting the NOCG and NNOCG from the SOCGs in a database of predetermined baseline OC grids, and the HOCG from an historical database of SOCGs of prior engine starts. 8. The method for controlling a vehicle according to claim 6 , further comprising: by the at least one controller: generating a cranking torque compensation factor according to a mechanical damper model of the transmission, calibrating the engine cranking torque with the compensation factor, and adjusting a gear ratio of the transmission according to the calibrated start profile and the calibrated engine cranking torque. 9. The method for controlling a vehicle according to claim 6 , further comprising: by the at least one controller, further coupled with an engine start OC and noise and vibration recorder: generating and storing with the recorder in a database of HOCGs, new HOCGs for each engine start that includes a minimum noise and vibration metric (MNVM).