Apparatus and method for engine stop position control

What is claimed is: 1. An electric starter system for an internal combustion engine having a flywheel with a flywheel gear, the flywheel connected to an engine crankshaft, the electric starter system comprising: a pinion gear; a pinion solenoid device coupled to the pinion gear; a starter motor that is selectively connectable to the flywheel of the engine via the pinion gear; and a controller in communication with the pinion solenoid device and the starter motor, the controller being configured to: in response to an engine auto-stop signal: command the engine to turn off; determine an engine speed of the engine after being turned off; command, in response to the engine speed being less than a first threshold speed, a control current be delivered to the pinion solenoid device at a peak current level to thereby translate the pinion gear into contact with the flywheel and the motor; command, in response to the engine speed being less than a second threshold speed, pulse width modulation (PWM) excitation to the starter motor to cause rotation of the starter motor to thereby fully engage the pinion gear with the flywheel and to cause rotation of the engine crankshaft to a predetermined crank angle; cease supplying PWM excitation to the starter motor when the engine crankshaft has reached the predetermined crank angle; transmit pulse width modulation (PWM) pinion control signals at varying voltages to deliver the control current to the pinion solenoid device at a fluctuating holding current level after the pinion gear is fully engaged with the flywheel, the holding current level being a non-zero value less than the peak current level; and in response to an engine auto-start signal: command delivery of motor torque from the starter motor, through the pinion gear, and to the flywheel while maintaining the control current at the holding current level for a duration sufficient for starting the engine. 2. The electric starter system of claim 1 comprising two independently controllable devices for delivering current to the starter motor. 3. The electric starter system of claim 2 , wherein one of the two independently controllable devices for delivering current to the starter motor comprises a motor solenoid, and the other of the two independently controllable devices for delivering current to the starter motor comprises a semiconductor switching device. 4. The electric starter system of claim 3 , wherein the pulse width modulation (PWM) excitation to the starter motor is supplied by the semiconductor switching device. 5. The electrical starter system of claim 3 , wherein excitation to the starter motor to deliver motor torque from the starter motor, through the pinion gear, and to the flywheel while maintaining the control current at the holding current level for a duration sufficient for starting the engine is supplied by the motor solenoid. 6. The electric starter system of claim 1 , wherein the pinion solenoid device and the starter motor are powered via an auxiliary voltage bus having a nominal voltage level of 15V or less. 7. A method for controlling an electric starter system for an internal combustion engine having a flywheel connected to an engine crankshaft, the method comprising: commanding, responsive to an engine auto-stop signal, the engine to turn off; determining, via a controller, when an engine speed of the engine is less than a first threshold speed; commanding, responsive to the engine speed being less than the first threshold speed, delivery of a control current to a pinion solenoid device via the controller at a peak current level to thereby translate a pinion gear connected to the pinion solenoid device into contact with the flywheel; commanding, responsive to the engine speed less than a second threshold speed, rotation of a starter motor to thereby fully engage the pinion gear with the flywheel and to rotate the engine crankshaft to a predetermined crank angle; transmitting pulse width modulation (PWM) pinion control signals at varying voltages to deliver the control current to the pinion solenoid device at a fluctuating holding current level, that is a non-zero value less than the peak current level, after the pinion gear is fully engaged with the flywheel; commanding via the controller, responsive to an engine auto-start signal, delivery of motor torque from the starter motor, through the pinion gear, and to the flywheel while maintaining the control current at the holding current level; and maintaining the motor torque via the controller for a duration sufficient for starting the engine. 8. The method of claim 7 , wherein the electric starter system comprises two independently controllable devices for delivering current to the starter motor. 9. The method of claim 8 , wherein one of the two independently controllable devices for delivering current to the starter motor comprises a motor solenoid, and the other of the two independently controllable devices for delivering current to the starter motor comprises a semiconductor switching device. 10. The method of claim 9 , wherein the pulse width modulation (PWM) excitation to the starter motor is supplied by the semiconductor switching device. 11. The method of claim 9 , wherein excitation to the starter motor to deliver motor torque from the starter motor, through the pinion gear, and to the flywheel while maintaining the control current at the holding current level for a duration sufficient for starting the engine is supplied by the motor solenoid. 12. The method of claim 7 , wherein the pinion solenoid device and the starter motor are powered via an auxiliary voltage bus having a nominal voltage level of 15V or less. 13. A powertrain comprising; an internal combustion engine having a flywheel with a flywheel gear, the engine having a crankshaft connected to the flywheel; a transmission connected to the engine; a load coupled to the transmission; a power source configured to output electric current; a pinion gear; a pinion solenoid device coupled to the pinion gear and configured to activate in response to electric current from the power source to thereby move the pinion gear into meshing contact with the flywheel gear of the flywheel; a starter motor with a motor gear that is selectively connectable to the flywheel gear of the flywheel of the engine via the pinion gear by activating the pinion solenoid device; and a controller in communication with the pinion solenoid device and the starter motor, the controller being configured to: in response to an engine auto-stop signal, command the engine to turn off; determine an engine speed of the engine after being turned off; command, in response to the engine speed being less than a first threshold speed, a control current be delivered to the pinion solenoid device at a peak current level to thereby translate the pinion gear into contact with the flywheel and the motor; command, in response to a predetermined delay time having elapsed after beginning the delivery of the control current to the pinion solenoid device at the peak current level, pulse width modulation (PWM) pinion solenoid control signals at varying voltages to deliver the control current to the pinion solenoid device at a fluctuating holding current level, the holding current level being a non-zero value less than the peak current level, command, in response to the engine speed being less than a second threshold speed, pulse width modulation (PWM) motor control signals be delivered to the starter motor to cause rotation of the starter motor to thereby fully engage the pinion gear with the flywheel and to cause rotation of the engine crankshaft to a