Method and apparatus for controlling an actuatable protection device with rough terrain and airborne detection

Having described the invention, the following is claimed: 1 . A vehicle safety system for a vehicle, comprising: an actuatable controlled restraint (ACR) including a seatbelt for restraining a vehicle occupant, the ACR being actuatable to control payout and retraction of the seatbelt; and a controller configured to determine operating conditions of the vehicle and to control the actuation of the ACR in response to the determined operating conditions of the vehicle, wherein the ACR has a normal restraint condition and an enhanced restraint condition, wherein the controller is configured to implement a longitudinal acceleration airborne classification algorithm for classifying vehicle airborne conditions in response to vehicle longitudinal accelerations measured along a vehicle X-axis, wherein the controller is configured to implement a lateral acceleration airborne classification algorithm for classifying vehicle airborne conditions in response to vehicle lateral accelerations measured along a vehicle Y-axis, wherein the controller is configured to implement a vertical acceleration airborne classification algorithm for classifying vehicle airborne conditions in response to vehicle vertical accelerations measured along a vehicle Z-axis, wherein the controller is configured to implement a roll acceleration airborne classification algorithm for classifying vehicle airborne conditions in response to vehicle roll accelerations measured about the vehicle X-axis, and wherein the controller is configured to actuate the ACR from the normal restraint condition to the enhanced restraint condition in response to determining abnormal driving conditions of the vehicle based at least on the classified vehicle airborne conditions. 2 . The vehicle safety system recited in claim 1 , wherein the ACR in the normal restraint condition is configured to apply a comparatively light retraction force sufficient to take up seatbelt webbing and tension the seatbelt across the occupant while, at the same time, being configured to payout the seatbelt webbing in response to occupant movement, and wherein the ACR in the enhanced restraint condition is configured to increase the retraction force applied to the seatbelt webbing and to increase a resistance to seatbelt webbing payout in response to occupant movement. 3 . The vehicle safety system recited in claim 1 , wherein the controller is an airbag controller (ACU) comprising: an ACU_X accelerometer configured to measure vehicle accelerations along the vehicle X-axis and generate a signal indicative thereof; an ACU_Y accelerometer for measuring vehicle accelerations along the vehicle Y-axis and generate a signal indicative thereof; an ACU_Z accelerometer for measuring vehicle accelerations along the vehicle Z-axis and generate a signal indicative thereof; and a ROLL sensor for measuring vehicle roll accelerations about the vehicle X-axis of the vehicle and producing generate a signal indicative thereof, and wherein the ACU is configured to determine the abnormal driving conditions of the vehicle in response to the signals from the ACU_X, ACU_Y, ACU_Z, and ROLL sensors. 4 . The vehicle safety system recited in claim 1 , wherein the controller is configured to implement a vertical acceleration airborne confirmation algorithm for confirming the vehicle airborne condition in response to vehicle vertical accelerations measured along the vehicle Z-axis. 5 . The vehicle safety system recited in claim 4 , wherein the vertical acceleration airborne confirmation algorithm is configured to determine a landed condition of the vehicle in response to vehicle vertical accelerations measured along the vehicle Z-axis. 6 . The vehicle safety system recited in claim 4 , wherein the controller is configured to determine the vehicle airborne condition in response to classifying the vehicle airborne condition and confirming the vehicle airborne condition. 7 . The vehicle safety system recited in claim 6 , wherein the controller is configured to determine the vehicle airborne condition further in response to determining that a vehicle off-road condition has not been determined. 8 . The vehicle safety system recited in claim 7 , wherein the controller is configured to implement an R_ANGLE off-road classification metric to classify the vehicle off-road condition, the R_ANGLE off-road classification metric evaluating a vehicle R_ANGLE over time and classifying the vehicle off-road condition in response to the R_ANGLE crossing both an upper threshold and a lower threshold within a predetermined amount of time in any order. 9 . A vehicle safety system for a vehicle, comprising: an actuatable controlled restraint (ACR) including a seatbelt for restraining a vehicle occupant, the ACR being actuatable to control payout and retraction of the seatbelt; and a controller configured to determine operating conditions of the vehicle and to control the actuation of the ACR in response to the determined operating conditions of the vehicle, wherein: the ACR has a normal restraint condition and an enhanced restraint condition; the controller is configured to implement a longitudinal acceleration airborne metric that evaluates vehicle longitudinal accelerations measured along a vehicle X-axis over time, the longitudinal acceleration airborne metric defining a threshold having a predetermined bandwidth that extends above and below a zero of the longitudinal acceleration, wherein the longitudinal acceleration airborne metric is configured to determine that the vehicle is in a vehicle airborne condition in response to a magnitude of the longitudinal acceleration exceeding and falling back within the threshold, the longitudinal acceleration airborne metric maintaining the vehicle airborne condition determination while the longitudinal acceleration remains within the threshold; the controller is configured to implement a lateral acceleration airborne metric that evaluates vehicle lateral accelerations measured along a vehicle Y-axis over time, the lateral acceleration airborne metric defining a threshold having a predetermined bandwidth that extends above and below a zero of the lateral acceleration, wherein the lateral acceleration airborne metric is configured to determine that the vehicle is in the vehicle airborne condition in response to a magnitude of the lateral acceleration exceeding and falling back within the threshold, the lateral acceleration airborne metric maintaining the vehicle airborne condition determination while the lateral acceleration remains within the threshold; the controller is configured to implement a roll acceleration airborne metric that evaluates vehicle roll accelerations measured about the vehicle X-axis over time, the roll acceleration airborne metric defining a threshold having a predetermined bandwidth that extends above and below a zero of the roll acceleration, wherein the roll acceleration airborne metric is configured to determine that the vehicle is in the vehicle airborne condition in response to a magnitude of the roll acceleration exceeding and falling back within the threshold, the roll acceleration airborne metric maintaining the vehicle airborne condition determination while the roll acceleration remains within the threshold; the controller is configured to implement a vertical acceleration airborne metric that evaluates vehicle vertical accelerations measured along a vehicle Z-axis over time, the vertical acceleration airborne metric defining a threshold having a predetermined bandwidth that extends above and below a zero of the vertical acceleration, wherein the vertical acceleration airborne metric is calibrated to compensate for the effects of gravity, wherein the vertical acceleration