Dynamic stabilization system and methods for an RC vehicle

We claim: 1. A radio-controlled (RC) vehicle comprising: an inertial measurement unit comprising: one or more accelerometers configured to output angular acceleration data associated with acceleration of the RC vehicle about one or more axes; and one or more angular rate sensors configured to output angular rotation data associated with rotation of the RC vehicle about the one or more axes; and a receiver configured to: receive the angular acceleration data and the angular rotation data from the inertial measurement unit; receive command data from a controller associated with the RC vehicle, wherein the command data includes steering data and throttle data; and in response to receiving the command data, the angular acceleration data, and the angular rotation data, control a wheel direction of at least one wheel of the RC vehicle. 2. The RC vehicle of claim 1 , wherein, in response to receiving the command data, the angular acceleration data, and the angular rotation data, the receiver is further configured to control a wheel speed of at least one wheel of the RC vehicle. 3. The RC vehicle of claim 1 , wherein the receiver is further configured to detect a reverse signal. 4. The RC vehicle of claim 3 , wherein the reverse signal is detected based on a comparison of the command data to at least one expected reverse command. 5. The RC vehicle of claim 2 , wherein the receiver is further configured to: determine whether a yaw rate exceeds a yaw rate threshold based on the angular rotation data; and in response to determining that the yaw rate exceeds the yaw rate threshold, reduce the wheel speed. 6. The RC vehicle of claim 1 , wherein the receiver is further configured to: determine whether a yaw rate exceeds a yaw rate threshold based on the angular rotation data; and in response to determining that the yaw rate exceeds the yaw rate threshold, change the wheel direction. 7. The RC vehicle of claim 1 , wherein the receiver controls the wheel direction based at least in part on a steering intervention function. 8. The RC vehicle of claim 7 , wherein the steering intervention function is based at least in part on a throttle command, a steering threshold intervention, a steering function, and the steering data. 9. The RC vehicle of claim 2 , wherein the receiver controls the wheel speed based at least in part on a throttle intervention function. 10. The RC vehicle of claim 9 , wherein the throttle intervention function is based at least in part on a throttle command, a throttle threshold intervention, a throttle threshold intervention delayed, and a throttle proportional intervention. 11. The RC vehicle of claim 1 , wherein the receiver is configured to control the wheel direction based at least in part on a varying steering priority. 12. The RC vehicle of claim 11 , wherein the steering priority varies based on the steering data and the angular rotation information. 13. A radio-controlled (RC) vehicle comprising: an inertial measurement unit comprising: one or more accelerometers configured to output angular acceleration data associated with acceleration of the RC vehicle about one or more axes; and one or more angular rate sensors configured to output angular rotation data associated with rotation of the RC vehicle about the one or more axes; and circuitry configured to: receive the angular acceleration data and the angular rotation data from the inertial measurement unit; receive command data from a controller associated with the RC vehicle, wherein the command data includes steering data and throttle data; and in response to receiving the steering data, the angular acceleration data, and the angular rotation data, control a wheel direction of at least one wheel of the RC vehicle. 14. The RC vehicle of claim 13 , wherein, in response to receiving the throttle data, the angular acceleration data, and the angular rotation data, the circuitry is further configured to control a wheel speed of at least one wheel of the RC vehicle. 15. The RC vehicle of claim 13 , wherein the circuitry is further configured to detect a reverse signal. 16. The RC vehicle of claim 15 , wherein the reverse signal is detected based on a comparison of the command data to at least one expected reverse command. 17. An inertial measurement unit for use in a radio-controlled (RC) vehicle, the inertial measurement unit comprising: one or more accelerometers configured to output angular acceleration data associated with acceleration of the RC vehicle about one or more axes; and one or more angular rate sensors configured to output angular rotation data associated with rotation of the RC vehicle about the one or more axes; and circuitry configured to: receive the angular acceleration data and the angular rotation data from the inertial measurement unit; receive command data from a controller associated with the RC vehicle, wherein the command data includes steering data and throttle data; and in response to receiving the steering data, the angular acceleration data, and the angular rotation data, control a wheel direction of at least one wheel of the RC vehicle. 18. The inertial measurement unit of claim 17 , wherein, in response to receiving the throttle data, the angular acceleration data, and the angular rotation data, the circuitry is further configured to control a wheel speed of at least one wheel of the RC vehicle. 19. The inertial measurement unit of claim 17 , wherein the circuitry is further configured to detect a reverse signal. 20. The inertial measurement unit of claim 19 , wherein the reverse signal is detected based on a comparison of the command data to at least one expected reverse command.