Toe optimization system for a vehicle

The invention claimed is: 1. A toe optimization system for a vehicle having first and second rear wheels defining a rear toe angle and a plurality of sensors providing respective data, the system comprising: first and second actuators operatively connected to the first and second rear wheels, respectively, and configured to vary the rear toe angle; a controller operatively connected to the plurality of sensors and having a processor and tangible, non-transitory memory on which is recorded instructions for executing a method for controlling the rear toe angle; wherein the first rear wheel is configured to be in contact with a first contact surface such that a first coefficient of friction is defined between the first rear wheel and the first contact surface; wherein the second rear wheel is configured to be in contact with a second contact surface such that a second coefficient of friction is defined between the second rear wheel and the second contact surface; and wherein execution of the instructions by the processor causes the controller to: select one of a plurality of vehicle states based on the respective data from at least one of the plurality of sensors, each one of the plurality of vehicle states having a respective toe setting; and actuate the first and second actuators via a toe command to vary the rear toe angle to the respective toe setting corresponding to the selected one of the plurality of vehicle states; wherein prior to the selection of one of the plurality of vehicle states, the controller is configured to: determine if at least one of the first and second coefficients of friction is at or below a threshold friction value; and if at least one of the first and second coefficients of friction is at or below the threshold friction value, then actuate the first and second actuators via the toe command to vary the rear toe angle to a predefined opt-out setting. 2. The system of claim 1 , wherein prior to actuating the first and second actuators via the toe command, the controller is configured to: calibrate the respective toe setting corresponding to the selected one of the plurality of vehicle states based at least partially on a speed of the vehicle. 3. The system of claim 1 , wherein after actuating the first and second actuators, the controller is further configured to: obtain respective current actuator positions of the first and second actuators via respective actuator position sensors; obtain respective current toe positions of the first and second rear wheels via respective toe position sensors; and revise the toe command based at least partially on the respective current actuator positions and the respective current toe positions. 4. A vehicle comprising: first and second rear wheels defining a rear toe angle; first and second actuators operatively connected to the first and second rear wheels, respectively, and configured to vary the rear toe angle; a controller operatively connected to the first and second actuators and having a processor and tangible, non-transitory memory on which is recorded instructions for executing a method for controlling the rear toe angle; a plurality of sensors operatively connected to and configured to communicate respective data to the controller, the plurality of sensors including a steering angle sensor configured to communicate a steering angle to the controller; wherein the first rear wheel is configured to be in contact with a first contact surface such that a first coefficient of friction is defined between the first rear wheel and the first contact surface; wherein the second rear wheel is configured to be in contact with a second contact surface such that a second coefficient of friction is defined between the second rear wheel and the second contact surface; wherein execution of the instructions by the processor causes the controller to: select one of a plurality of vehicle states based on the respective data from at least one of the plurality of sensors, each one of the plurality of vehicle states having a respective toe setting; and actuate the first and second actuators via a toe command to vary the rear toe angle to the respective toe setting corresponding to the selected one of the plurality of vehicle states; wherein prior to the selection of one of the plurality of vehicle states, the controller is configured to: determine if at least one of the first and second coefficients of friction is at or below a threshold friction value; and if at least one of the first and second coefficients of friction is at or below the threshold friction value, then actuate the first and second actuators via the toe command to vary the rear toe angle to a predefined opt-out setting. 5. The vehicle of claim 4 , wherein prior to actuating the first and second actuators, the controller is configured to: calibrate the respective toe setting corresponding to the selected one of the plurality of vehicle states based at least partially on a speed of the vehicle. 6. The vehicle of claim 4 , wherein after actuating the first and second actuators, the controller is further configured to: obtain respective current actuator positions of the first and second actuators via respective actuator position sensors; obtain respective current toe positions of the first and second rear wheels via respective toe position sensors; and revise the toe command based at least partially on the respective current actuator positions and the respective current toe positions. 7. The vehicle of claim 4 , wherein: the plurality of sensors include a speed sensor configured to communicate a vehicle speed to the controller; and the plurality of vehicle states includes a first vehicle state characterized by the steering angle being below a first steering angle threshold and the vehicle speed being below a speed threshold. 8. The vehicle of claim 4 , wherein: the plurality of sensors include a speed sensor configured to communicate a vehicle speed to the controller; and the plurality of vehicle states includes a second vehicle state characterized by the steering angle being at or above the first steering angle threshold and the vehicle speed being above the speed threshold. 9. The vehicle of claim 4 , wherein: the plurality of sensors include a lateral sensor configured to communicate a lateral acceleration of the vehicle to the controller; and the plurality of vehicle states includes a third vehicle state characterized by the steering angle being above the first steering angle threshold and the lateral acceleration being above a threshold lateral acceleration. 10. The vehicle of claim 4 , wherein: the plurality of sensors include a brake pedal position sensor configured to communicate a brake pedal travel to the controller; the plurality of vehicle states includes a fourth vehicle state characterized by a rate of change of the steering angle being above a threshold angle change and the brake pedal travel being above a threshold pedal travel in a threshold time. 11. The vehicle of claim 4 , wherein: the plurality of sensors include a brake pedal position sensor configured to communicate a brake pedal travel to the controller; the plurality of vehicle states includes a fifth vehicle state characterized by the steering wheel angle being zero degrees and the brake pedal being above zero; and the plurality of vehicle states includes a sixth vehicle state characterized by the steering wheel angle being above the first steering angle threshold and the brake pedal travel being above zero. 12. The vehicle of claim 4 , wherein: the plurality of sensors include first and second rear speed sensors operatively conne