Suspension with active damping to tune caster dynamics

What is claimed is: 1. A suspension assembly for a vehicle having a frame, the suspension assembly comprising: a control arm pivotably coupled to the frame; a knuckle coupled to the control arm and adapted to support a wheel hub for rotation relative to the knuckle; a spring mounted between the frame and either the control arm or the knuckle; a damper having an adjustable damping force and including a first end mounted to the frame above a rotational axis of the wheel hub and a second end mounted below the first end such that a change in caster angle of the knuckle extends or contracts the damper; and a control module in communication with the damper and configured to adjust a damping force of the damper based on an actual or predicted change in caster angle of the knuckle, the control module being configured to increase the damping force in a direction that resists a change in the caster angle. 2. The suspension assembly of claim 1 , wherein the damper is disposed either forward or rearward of a kingpin axis of the suspension assembly. 3. The suspension assembly of claim 1 , wherein one of the spring and the damper is disposed forward of the kingpin axis and the other of the spring and the damper is disposed rearward of the kingpin axis. 4. The suspension assembly of claim 1 , wherein the second end of the damper is mounted to the knuckle. 5. The suspension assembly of claim 1 , further comprising a first sensor configured to detect a first characteristic of the vehicle, wherein the control module is configured to receive a first signal representative of the first characteristic from the first sensor and to adjust the damping force of the damper based on the first characteristic. 6. The suspension assembly of claim 5 , wherein the first characteristic is one of an acceleration of the vehicle, a deceleration of the vehicle, and a change in angular position of the knuckle relative to the frame. 7. The suspension assembly of claim 5 , wherein the control module is configured to calculate the caster angle based on the first signal and at least one second characteristic of the vehicle. 8. The suspension assembly of claim 7 , wherein the at least one second characteristic is one of a ride height and a length of the damper. 9. The suspension assembly of claim 8 , further comprising a second sensor configured to detect a length of the damper. 10. The suspension assembly of claim 1 , further comprising a toe link and a camber link, the toe link including a first end mounted to the knuckle at a first location on the knuckle, a second end coupled to the frame, and a first rigid body extending between the first and second ends, the camber link including a third end mounted to the knuckle at a second location on the knuckle, a fourth end coupled to the frame, and a second rigid body extending between the third and fourth ends, the control arm being mounted to the knuckle at a third location on the knuckle. 11. The suspension assembly of claim 10 , wherein the second end of the damper is mounted to one of the control arm, the toe link, and the camber link. 12. The suspension assembly of claim 1 , further comprising a first bushing and a second bushing, the first and second bushings being mounted in a force transmission path between the knuckle and the frame and configured to provide the knuckle with a first degree of compliance in a first rotational direction and a second degree of compliance in a second direction, the first degree of compliance being greater than the second degree of compliance. 13. The suspension assembly of claim 12 , wherein the first bushing is mounted to the knuckle and the second bushing is mounted to one of the control arm, a toe link, and a camber link. 14. A suspension assembly for a vehicle having a frame, the suspension assembly comprising: a knuckle adapted to support a wheel hub for rotation relative to the knuckle; a plurality of control arms, each control arm including a first end coupled to the frame, a second end coupled to the knuckle, and a rigid body extending between the first and second ends of the control arm; a spring mounted between the frame and either the knuckle or one of the control arms; a damper having an adjustable damping force and including a first end coupled to the frame above a rotational axis of the wheel hub and a second end mounted below the first end to either the knuckle or one of the control arms such that a change in caster angle of the knuckle extends or contracts the damper; a first sensor configured to detect a first characteristic of the vehicle and output a first signal representative of the first characteristic; and a control module in communication with the damper and the sensor, the control module configured to receive the first signal and determine an actual or predicted change in caster angle of the knuckle based on the first characteristic, the control module configured to increase a damping force of the damper in a direction that resists the change in caster angle. 15. The suspension assembly of claim 14 , wherein the first characteristic is one of an acceleration of the vehicle, a deceleration of the vehicle, and a change in angular position of the knuckle relative to the frame. 16. The suspension assembly of claim 14 , wherein the control module is configured to calculate the caster angle based on the first characteristic and at least one second characteristic of the vehicle. 17. The suspension assembly of claim 16 , wherein the at least one second characteristic is one of a ride height and a length of the damper. 18. A method of controlling a caster angle of a knuckle of a vehicle, the vehicle including a damper having an adjustable damping force and including a first end coupled to a frame of the vehicle above a rotational axis of a wheel hub of the vehicle and a second end mounted below the first end to either the knuckle or a control arm of the vehicle such that a change in caster angle of the knuckle extends or contracts the damper, the method comprising: detecting at a first sensor a first characteristic of the vehicle; receiving at a control module a first input from the first sensor, the first input representative of the first characteristic; determining at the control module an actual or predicted change in caster angle of the knuckle based on the first input; and adjusting a damping force of the damper in a direction that resists the actual or predicted change in caster angle. 19. The method of claim 18 , wherein adjusting the damping force of the damper includes increasing the damping force in a first direction that resists rotation of the knuckle away from a preferred caster angle and decreasing the damping force in a second direction that that permits rotational change of the knuckle toward the preferred caster angle. 20. The method of claim 18 , wherein determining the actual or predicted change in caster angle includes calculating the caster angle based on at least one of an acceleration of the vehicle, a deceleration of the vehicle, a change in angular position of the knuckle, and a length of the damper.