Actively damping vertical oscillations of an elevator car

What is claimed is: 1. A system for damping vertical oscillations of an elevator car stopped at an elevator landing, the system comprising: an elevator traction sheave operable to receive a torque, wherein oscillations in the torque correspond to the vertical oscillations of the car stopped at the landing during a first mode of operation; a sensor operable to provide a sensor signal indicative of the torque; a controller operable to provide a control signal based on the sensor signal; and a motor operable to apply the torque to the sheave and drive the sensor signal towards a baseline value in response to receiving the control signal during a second mode of operation, wherein the driving of the sensor signal towards the baseline value reduces the vertical oscillations of the car; wherein the controller is operable to determine the baseline value based on changes in the sensor signal during at least a portion of at least one of the vertical oscillations of the car, and the baseline value is substantially equal to an average of the sensor signal during the at least one of the vertical oscillations of the elevator car. 2. The system of claim 1 , wherein the first mode of operation comprises a position control mode of operation, and the second mode of operation comprises a constant torque control mode of operation. 3. The system of claim 1 , wherein the motor is operable to rotate the sheave during the driving of the sensor signal towards the baseline value, and wherein the rotating of the sheave damps the vertical oscillations of the car. 4. The system of claim 1 , wherein the controller is operable to provide the control signal where an amplitude of at least a portion of at least one oscillation in the sensor signal is greater than a threshold. 5. The system of claim 1 , wherein the controller is operable to monitor the sensor signal during the second mode of operation, and to provide a second control signal where one of: an amplitude of at least a portion of at least one oscillation in the monitored sensor signal is less than a threshold; and the monitored sensor signal becomes substantially constant; and the motor is operable to hold the sheave at an angular position in response to receiving the second control signal and revert back from the second mode of operation to the first mode of operation. 6. The system of claim 1 , further comprising a brake operable to hold the sheave at an angular position in response to receiving a second control signal; wherein the motor reverts back to the first mode of operation from the second mode of operation upon provision of the second control signal; and wherein the controller is operable to monitor the sensor signal during the second mode of operation, and to provide the second control signal where one of: an amplitude of at least a portion of at least one oscillation in the monitored sensor signal is less than a threshold; and the monitored sensor signal becomes substantially constant. 7. The system of claim 1 , further comprising a second sensor operable to provide a second sensor signal indicative of an angular position of the sheave, wherein the controller is operable to signal the motor to hold the sheave at a substantially constant angular position during at least one of the vertical oscillations of the elevator car where a change in the second sensor signal is greater than a second threshold; determine at least one of an approximate maximum and an approximate minimum of the second sensor signal during the at least one of the vertical oscillations of the elevator car; and signal the motor to drive the sensor signal towards the baseline value approximately when or at a predetermined point in time after the maximum or the minimum of the sensor signal is reached. 8. The system of claim 1 , further comprising a second sensor operable to provide a second sensor signal indicative of an angular position of the sheave; and a brake operable to hold the sheave at a substantially constant angular position during at least one of the vertical oscillations of the elevator car where a change in the second sensor signal is greater than a second threshold; wherein the controller is operable to determine at least one of an approximate maximum and an approximate minimum of the second sensor signal during the at least one of the vertical oscillations of the elevator car, and signal the motor to drive the sensor signal towards the baseline value approximately when or at a predetermined point in time after the maximum or the minimum of the sensor signal is reached. 9. A method for damping vertical oscillations of an elevator car stopped at an elevator landing, wherein oscillations in a torque applied by a motor to an elevator traction sheave during a first mode of operation correspond to the vertical oscillations of the car, the method comprising: receiving a sensor signal indicative of the torque received by the sheave; processing the sensor signal with a controller to provide a control signal to the motor; driving the sensor signal towards a baseline value with the motor in response to receiving the control signal, wherein the driving of the sensor signal towards the baseline value reduces the vertical oscillations of the car; and determining the baseline value with the controller based on changes in the sensor signal during at least a portion of at least one of the vertical oscillations of the car, wherein the baseline value is substantially equal to an average of the sensor signal during the at least one of the vertical oscillations of the car. 10. The method of claim 9 , wherein the first mode of operation comprises a position control mode of operation; and the sensor signal is driven towards the baseline value during a second mode of operation that comprises a constant torque control mode of operation. 11. The method of claim 9 , wherein the driving of the sensor signal towards the baseline value causes the sheave to rotate, and wherein the rotating of the sheave damps the vertical oscillations of the car. 12. The method of claim 9 , wherein the controller provides the control signal where an amplitude of at least a portion of at least one oscillation in the sensor signal is greater than a threshold. 13. The method of claim 9 , further comprising monitoring the sensor signal during a second mode of operation; and holding the sheave at an angular position where one of changes in the monitored sensor signal are less than a threshold; and the monitored sensor signal becomes substantially constant. 14. The method of claim 9 , further comprising receiving a second sensor signal indicative of an angular position of the sheave; holding the sheave at a substantially constant angular position during at least one of the vertical oscillations of the car where a change in the second sensor signal is greater than a second threshold; determining at least one of an approximate maximum and an approximate minimum of the second sensor signal during the at least one of the vertical oscillations of the elevator car; and driving the sensor signal towards the baseline value approximately when or at a predetermined point in time after the maximum or the minimum of the sensor signal is reached. 15. The method of claim 9 , wherein the vertical oscillations of the elevator car are caused by intermittent stretching and contracting of one or more tension members connecting the car to the sheave. 16. The method of claim 15 , wherein one or more of the tension members comprises a belt.