Valve actuator assembly with current trim and fuel injector using same

What is claimed is: 1. A valve actuator assembly, comprising: a valve member movable between a first seat and a second seat; a spring member biasing the valve member toward the first seat; an actuator positioned to move the valve member toward the second seat against the spring member biasing when the actuator is energized, the actuator including an armature coupled to the valve member and a solenoid coil positioned to move the valve member using the armature when the solenoid coil is energized; and a controller in control communication with the actuator and configured to provide a first current to the actuator for an energizing period, remove the first current to the actuator to begin a post-energizing period, identify a return current in the solenoid coil having a magnitude less than or equal to a predetermined threshold indicative of a lack of return contact between the valve member and the first seat during the post-energizing period, and provide a second current to the actuator for a second energizing period, the second current being higher than the first current in response to the lack of contact. 2. The valve actuator assembly of claim 1 , wherein the controller is further configured to identify a return current in the solenoid coil having a magnitude greater than a predetermined threshold indicative of return contact between the valve member and the first seat responsive to the second current. 3. The valve actuator assembly of claim 2 , wherein the controller uses a feedback loop to increase the first current toward the second current. 4. The valve actuator assembly of claim 1 , wherein the armature includes a cobalt-iron alloy. 5. The valve actuator assembly of claim 4 , wherein the solenoid coil is disposed within a stainless steel case. 6. The valve actuator assembly of claim 1 , wherein the solenoid coil is disposed within a stainless steel case. 7. A method of operating a valve actuator assembly, the valve actuator assembly including a valve member movable between a first seat and a second seat, an actuator having a solenoid coil and an armature positioned to move the valve member toward the second seat using the armature when the solenoid coil is energized is energized, and a controller in control communication with the actuator, the method comprising steps of: biasing the valve member toward the first seat using a spring member; providing a first current from the controller to the solenoid coil for an energizing period; removing the first current to the solenoid coil to begin a post-energizing period; identifying a return current in the solenoid coil having a magnitude less than or equal to a predetermined threshold indicative of a lack of return contact between the valve member and the first seat during the post-energizing period; and providing a second current to the solenoid coil for a second energizing period, the second current being higher than the first current in response to the lack of return contact. 8. The method of claim 7 , further including identifying a return current in the solenoid coil having a magnitude greater than a predetermined threshold indicative of return contact between the valve member and the first seat responsive to the second current. 9. The method of claim 8 , further including using a feedback loop to increase the first current toward the second current. 10. The method of claim 7 , further including increasing a magnetic flux density of the armature by making the armature from a cobalt-iron alloy. 11. The method of claim 7 , further including decreasing transmission of magnetic flux from the solenoid coil using a stainless steel case, wherein the solenoid coil is disposed within the stainless steel case. 12. A fuel injector, comprising: an injector body; a valve actuator assembly disposed within the injector body and including: a valve member movable between a first seat and a second seat; an armature coupled to the valve member; a spring member biasing the valve member toward the first seat; and a solenoid coil positioned to move the valve member toward the second seat using the armature when the solenoid coil is energized; and a controller in control communication with the solenoid coil and configured to provide a first current to the solenoid coil for an energizing period, remove the first current to the solenoid coil to begin a post-energizing period, identify a return current in the solenoid coil having a magnitude less than or equal to a predetermined threshold indicative of a lack of return contact between the valve member and the first seat during the post-energizing period, and provide a second current to the solenoid coil for a second energizing period, the second current being higher than the first current in response to the lack of return contact. 13. The fuel injector of claim 12 , wherein the controller is further configured to identify a return current in the solenoid coil having a magnitude greater than a predetermined threshold indicative of return contact between the valve member and the first seat responsive to the second current. 14. The fuel injector of claim 13 , wherein the controller uses a feedback loop to increase the first current toward the second current. 15. The fuel injector of claim 14 , wherein the controller provides the first current in a first injection event and provides the second current in a second injection event. 16. The fuel injector of claim 12 , wherein the armature includes a cobalt-iron alloy. 17. The fuel injector of claim 16 , wherein the solenoid coil is disposed within a stainless steel case. 18. The fuel injector of claim 12 , wherein the solenoid coil is disposed within a stainless steel case. 19. The valve actuator assembly of claim 1 the controller is configured to identify a return current in the solenoid coil having a magnitude of zero. 20. The method of claim 7 wherein the magnitude of the return current is zero.