Electronic valve actuator with predictive self-calibrating torque controller

We claim: 1. An electronically controlled, electric motor-driven valve actuator, comprising: an electronic controller; an electric motor configured to cause a linear or rotational actuation of a valve according to a motor input received from the electronic controller, whereby application of said motor input to said electric motor determines a motor output force or torque that causes a valve force or torque to be applied to the valve; and a torque sensor configured to directly or indirectly measure the valve force or torque by measuring a sensed mechanical force or torque that results from application of an electric voltage or current to the electric motor; said electronic controller being configured to: A) store a motor configuration parameter set and a valve control requirement, wherein said valve control requirement includes a required force or torque to be applied to the valve; B) according to the stored motor configuration parameter set, determine a predicted motor input that, when applied to the electric motor, is predicted to cause the required force or torque to be applied to the valve; C) determine a predicted sensed force or torque that will be measured by the torque sensor when the required force or torque is applied to the valve; D) apply the predicted motor input to the electric motor; E) receive from the torque sensor a measured sensed force or torque; F) compare the measured sensed force or torque with the predicted sensed force or torque; and G) if a difference between the measured sensed force or torque and the predicted sensed force or torque exceeds a specified limit, modify the stored motor configuration parameter set according to the difference between the measured sensed force or torque and the predicted sensed force or torque. 2. The valve actuator of claim 1 , further comprising a gear train configured to convert the motor output force or torque into the valve force or torque, and wherein the motor configuration parameter set includes parameters relevant to mechanical properties of the gear train. 3. The valve actuator of claim 1 , wherein the sensed force or torque is the motor output force or torque. 4. The valve actuator of claim 1 , wherein the sensed force or torque is the valve force or torque. 5. The valve actuator of claim 1 , wherein the valve actuator includes a plurality of torque sensors, wherein a first of the torque sensors is configured to measure the motor output force or torque, while a second of the torque sensors is configured to measure the valve force or torque. 6. The valve actuator of claim 1 , wherein the electric motor is driven by alternating current, and is controlled by a variable frequency motor drive with field oriented control. 7. The valve actuator of claim 1 , wherein the electric motor is driven by direct current, and is controlled by a variable direct current source. 8. The valve actuator of claim 1 , wherein the electronic controller is further configured to determine an initial motor control parameter set, said determination including sequentially applying a plurality of motor inputs to the electric motor, and for each of the applied motor inputs recording a corresponding sensed force or torque as measured by the torque sensor. 9. The valve actuator of claim 1 , wherein the electronic controller is configured to periodically or continuously repeat steps B) through G) of claim 1 . 10. The valve actuator of claim 9 , wherein the electronic controller is further configured to detect a failure of the torque sensor, and upon said failure detection to continue repeating steps B) through D) of claim 1 . 11. The valve actuator of claim 10 , wherein the electronic controller is configured to determine that the torque sensor has failed when the electronic controller does not receive an expected measured sensed force or torque, or if a measured sensed force or torque received from the sensor is outside of a specified range of operational values. 12. The valve actuator of claim 9 , wherein the predicted motor input applied to the electric motor includes a current or voltage applied to the electric motor according to a current or voltage measurement provided by a current or voltage sensor, and wherein, upon detection that the current or voltage sensor has failed, the electronic controller is further configured to implement reactive control of the electric motor based on the measured sensed forces or torques. 13. The valve actuator of claim 1 , further comprising a valve position sensor configured to measure a position of the valve and communicate the measured valve position to the electronic controller. 14. The valve actuator of claim 1 , further comprising a rotor position sensor configured to measure a rotational position of a rotor included in the electric motor, and to communicate the measured rotor position to the electronic controller. 15. A method of actuating a control valve, the method comprising: providing a valve actuator comprising an electronic controller, an electric motor configured to cause a linear or rotational actuation of a valve according to a motor input received from the electronic controller, whereby application of said motor input to said electric motor determines a motor output force or torque that causes a valve force or torque to be applied to the valve, and a torque sensor configured to directly or indirectly measure the valve force or torque by measuring a sensed mechanical force or torque resulting from application of a voltage or electric current to the electric motor; and causing the electronic controller to: A) store a motor configuration parameter set and a valve control requirement, wherein said valve control requirement includes a required force or torque to be applied to the valve; B) according to the stored motor configuration parameter set, determine a predicted motor input that, when applied to the electric motor, is predicted to cause the required force or torque to be applied to the valve; C) determine a predicted sensed force or torque that will be measured by the torque sensor when the required force or torque is applied to the valve; D) apply the predicted motor input to the electric motor; E) receive from the torque sensor a measured sensed force or torque; F) compare the measured sensed force or torque with the predicted sensed force or torque; and G) if a difference between the measured sensed force or torque and the predicted sensed force or torque exceeds a specified limit, modify the stored motor configuration parameter set according to the difference between the measured sensed force or torque and the predicted sensed force or torque. 16. The method of claim 15 , wherein the method further comprises causing the electronic controller to determine an initial motor control parameter set, said determination including sequentially applying a plurality of motor inputs to the electric motor, and for each of the applied motor inputs recording a corresponding sensed force or torque as measured by the torque sensor. 17. The method of claim 15 , wherein the method further includes causing the electronic controller to periodically or continuously repeat steps B) through G) of claim 15 . 18. The method of claim 17 , further comprising determining by the electronic controller if the torque sensor has failed, and upon determining that the torque sensor has failed, continuing to repeat steps B) through D) of claim 15 . 19. The method of claim 15 , wherein the predicted motor input applied to the electric motor includes a current or volt