Vehicle motion estimation enhancement with radar data

What is claimed is: 1. A method comprising: obtaining radar data pertaining to one or more stationary objects in proximity to a vehicle via one or more radar sensors of the vehicle; tracking the one or more stationary objects, via a processor onboard the vehicle; calculating, via the processor onboard the vehicle, a first velocity value of the vehicle using sensor data from one or more additional vehicle sensors, other than radar sensors, in combination with a dynamic model for the vehicle; calculating, via the processor onboard the vehicle, a second velocity value of the vehicle using the radar data, based on the tracking of the one or more stationary objects; and comparing, via the processor onboard the vehicle, the first velocity value with the second velocity value, for use in implementing one or more active safety features of the vehicle. 2. The method of claim 1 , wherein: the step of tracking the one or more stationary objects comprises tracking the one or more objects in proximity to the vehicle over time using the radar data while the vehicle is in a steady state; and the method further comprises verifying that the one or more objects are stationary objects based on the tracking. 3. The method of claim 1 , further comprising: determining a range and range rate for the one or more stationary objects with respect to the vehicle based on the radar data; wherein the step of calculating the second velocity value comprises calculating the second velocity value using the range and the range rate. 4. The method of claim 3 , further comprising: measuring a yaw rate for the vehicle; and obtaining a location and azimuth angle rate of one or more radar sensors of the vehicle with respect to a center of gravity of the vehicle via the radar data; wherein the step of calculating the second velocity value comprises calculating the second velocity value using the range, the range rate, the location, the azimuth angle rate, and the yaw rate. 5. The method of claim 1 , further comprising: providing a notification if a difference between the first velocity value and the second velocity value exceeds a predetermined threshold value. 6. A system comprising: one or more radar sensors of a vehicle, the one or more radar sensors configured to at least facilitate obtaining radar data pertaining to one or more stationary objects in proximity to the vehicle; and a processor disposed onboard the vehicle and coupled to the one or more radar sensors, the configured to at least facilitate: tracking the one or more stationary objects; calculating a first velocity value of the vehicle using sensor data from one or more additional vehicle sensors, other than radar sensors, in combination with a dynamic model for the vehicle; calculating a second velocity value of the vehicle using the radar data, based on the tracking of the one or more stationary objects; and comparing the first velocity value with the second velocity value, for use in implementing one or more active safety features of the vehicle. 7. The system of claim 6 , wherein the processor is further configured to at least facilitate: tracking the one or more objects in proximity to the vehicle over time using the radar data while the vehicle is in a steady state; and verifying that the one or more objects are stationary objects based on the tracking. 8. The system of claim 6 , wherein: the one or more radar sensors are configured to at least facilitate obtaining a range and range rate for the one or more stationary objects with respect to the vehicle; and the processor is configured to at least facilitate calculating the second velocity value using the range and the range rate. 9. The system of claim 8 , further comprising: a yaw sensor configured to at least facilitate measuring a yaw rate of the vehicle; wherein the processor is configured to at least facilitate: obtaining a location and azimuth angle rate of the one or more radar sensors of the vehicle with respect to a center of gravity of the vehicle via the radar data; calculating the second velocity value using the range, the range rate, the location, the azimuth angle rate, and the yaw rate. 10. The system of claim 6 , providing a notification if a difference between the first velocity value and the second velocity value exceeds a predetermined threshold value. 11. A vehicle comprising: a body; one or more radar sensors configured to at least facilitate obtaining radar data pertaining to one or more stationary objects in proximity to the vehicle; one or more additional vehicle sensors, other than radar sensors, that are configured to obtain sensor data pertaining to vehicle movement; and a processor disposed within the body and coupled to the one or more radar sensors, the processor configured to at least facilitate: tracking the one or more stationary objects, via a processor onboard the vehicle; calculating a first velocity value of the vehicle using sensor data from one or more additional vehicle sensors, other than radar sensors, in combination with a dynamic model for the vehicle; calculating a second velocity value of the vehicle using the radar data, based on the tracking of the one or more stationary objects; and comparing the first velocity value with the second velocity value, for use in implementing one or more active safety features of the vehicle. 12. The vehicle of claim 11 , wherein the processor is further configured to at least facilitate: tracking the one or more objects in proximity to the vehicle over time using the radar data while the vehicle is in a steady state; and verifying that the one or more objects are stationary objects based on the tracking. 13. The method of claim 1 , further comprising: implementing one or more of the active safety features of the vehicle, via the processor, using the comparison of the first velocity value with the second velocity value. 14. The method of claim 13 , wherein the step of implementing the one or more of the active safety features comprises: controlling braking for the vehicle by implementing one or more braking active safety features of the vehicle, via the processor, using the comparison of the first velocity value with the second velocity value. 15. The method of claim 13 , wherein the step of implementing the one or more of the active safety features comprises: controlling braking for the vehicle by implementing one or more braking active safety features of the vehicle, via the processor, using the comparison of the first velocity value with the second velocity value. 16. The method of claim 13 , wherein the active safety feature is selected from the group consisting of automatic braking, braking assist, steering assist, traction control, electronic stability control, lane departure warning, and lane change awareness. 17. The method of claim 13 , wherein the step of implementing the one or more of the active safety features comprises: implementing one or more of the active safety features of the vehicle, via the processor, using the first velocity value, when the vehicle is not in a steady state and a difference between the second velocity value and the first velocity value is less than a predetermined threshold; and implementing the one or more of the active safety features of the vehicle, via the processor, using the second velocity value, instead of the first velocity value, when the vehicle is not in a steady state and the difference between the second velocity value and the first velocity value is greater than a predetermined threshold.