Retrofit damper system with back EMF position and end stop detection

What is claimed is: 1. A damper system configured for installation in a duct, the damper system comprising: a damper assembly configured to be disposed within the duct, the damper assembly including a damper blade movable between a closed end position and an open end position and an electric damper motor configured to drive the damper blade to a desired position that is at or between the closed end position and the open end position; and a controller configured to output a drive signal configured to cause the electric damper motor to drive the damper blade to the desired position, wherein the controller is configured to: create a plurality of interruptions in the drive signal while driving the damper blade toward the desired position; and cause a sense circuit to sense a back EMF signal generated by the electric damper motor during each interruption of the plurality of interruptions in the drive signal; and estimate a current position of the damper blade between the closed end position and the open end position based at least in part on the back EMF signals sensed during the plurality of interruptions. 2. The damper system of claim 1 , wherein the controller is configured to determine that the current position of the damper blade corresponds to the closed end position when the drive signal drives the damper blade toward the closed end position and the controller determines that the damper has stopped moving based on at least one sensed back EMF signal. 3. The damper system of claim 2 , wherein the controller is configured to reset resets the estimated current position to the closed end position when the controller determines that the current position of the damper blade corresponds to the closed end position. 4. The damper system of claim 1 , wherein the controller is configured to determine that the current position of the damper blade corresponds to the open end position when the drive signal drives the damper blade toward the open end position and the controller determines that the damper has stopped moving based on at least one sensed back EMF signal. 5. The damper system of claim 4 , wherein the controller is configured to reset the estimated current position to the open end position when the controller determines that the current position of the damper blade corresponds to the open end position. 6. The damper system of claim 1 , wherein the controller is configured to estimate the estimated position of the damper blade based at least in part on integrating a plurality of back EMF signals. 7. The damper system of claim 1 , wherein the controller is configured to: receive a requested position of the damper blade; drive the damper blade towards the requested position while periodically estimating the position; and stop driving the damper blade when the absolute value of the estimated current position minus the requested position is less than a limit. 8. The damper system of claim 6 , wherein the controller is configured to take an estimated position reset action after a specified number of damper blade moves, and wherein the estimated position reset action comprises moving the damper blade to either the closed end position or the open end position, resetting the estimated current position, zeroing a count of moves since a last estimated position reset action, and then moving the damper blade toward the requested position. 9. The damper system of claim 7 , wherein the controller is configured to set a new value for the specified number of damper blade moves, where the new value is a count of moves that is present when the controller determines the damper blade has reached a fully open or a fully closed position when the controller moves the damper blade toward the requested position. 10. The damper system of claim 1 , wherein the controller is configured to determine a velocity constant based on driving the damper blade over a full range of motion from a fully open position to a fully closed position while integrating the back EMF signals, and wherein the controller is configured to determine the estimated current position of the damper blade using the velocity constant. 11. The damper system of claim 1 , wherein the controller is configured to recalibrate the estimated current position of the damper blade by at least sensing a back EMF that is less than a threshold. 12. The damper system of claim 1 , further comprising a control module having a housing, wherein the housing is configured to be secured to a register boot coupled to the duct, and wherein the control module includes the controller. 13. The damper system of claim 1 , further comprising a power supply having a housing, wherein the housing is configured to be secured to a register boot coupled to the duct, and wherein the power supply is configured to provide power to the controller. 14. The damper system of claim 1 , wherein the damper assembly further comprises a damper frame configured to be disposed within the duct, wherein the damper blade is pivotally mounted to the damper frame. 15. The damper system of claim 14 , wherein the damper blade is substantially parallel with the damper frame in the closed end position, and wherein the damper blade is substantially perpendicular to the damper frame in the open end position. 16. The damper system of claim 14 , wherein the damper blade has a blade periphery having an at least substantially obround shape and the damper frame has a frame periphery that is a substantially obround shape. 17. The damper system of claim 14 , further comprising a deployment member operably coupled to the damper frame, the deployment member configured to facilitate placement of the damper frame through a register boot coupled to the duct. 18. The damper system of claim 14 , wherein the controller is configured to estimate the current position of the damper blade relative to the damper frame. 19. A damper system configured for installation in a duct, the damper system comprising: a damper assembly configured to be disposed within the duct, the damper assembly including a damper blade movable between a closed end position and an open end position and an electric damper motor configured to drive the damper blade to a desired position that is at or between the closed end position and the open end position; a controller configured to output a drive signal configured to cause the electric damper motor to drive the damper blade to the desired position, wherein the controller is configured to: create a plurality of interruptions in the drive signal while driving the damper blade toward the desired position; determine, based on a signal from a sense circuit, a back EMF signal generated by the electric damper motor during each interruption of the plurality of interruptions in the drive signal; estimate a current position of the damper blade between the closed end position and the open end position based at least in part on integrating a plurality of back EMF signals sensed during the plurality of interruptions; determine that the current position of the damper blade corresponds to the closed end position when the drive signal drives the damper blade toward the closed end position and the controller determines that the damper has stopped moving based on the sensed back EMF signal; and determine that the current position of the damper blade corresponds to the open end position when the drive signal drives the damper blade toward the open end position and the controller determines that the damper has stopped moving based on the sensed back EMF signal.