Abstract: A magnetorheological (MR) damper includes a damper tube, a movable non-MR damper piston, and a non-movable MR damper piston. The damper tube has substantially hermetically separated first and second chambers, wherein the first chamber contains a non-MR fluid and the second chamber contains an MR fluid. The non-MR damper piston is located in the first chamber and is slidable with respect to the damper tube. The MR damper piston has a longitudinal axis and an electric coil, is located in the second chamber, and is fixedly attached to the damper tube. Sliding the non-MR damper piston with respect to the damper tube causes movement of at least some of the MR fluid longitudinally past the electric coil.

Abstract: Method for determining a present coil temperature of a coil of a magnetorheological (MR) damper of an operating automotive vehicle, wherein the coil is powered by an output of a controller connected to the coil through a conductor. One step includes calculating a coil-plus-conductor resistance from the voltage and the current of the output of the controller when the controller applies a test current to the coil and the conductor. Another step includes calculating the present coil temperature using at least the coil-plus-conductor resistance and compensating for the resistance of the conductor.

Abstract: A suspension control for vehicle dampers uses a trimset value to compensate signals from relative body/wheel position sensors associated with the dampers. Each trimset value is determined by recording a sensor value with the body and wheel in a predetermined relative state, such as by lifting the vehicle until the associated wheel is free of the ground and hanging in a low limit position determined by the suspension apparatus. In vehicle operation, the trimset value is used as an offset to the relative position sensor signal to accurately determine damper position relative to its compression and rebound limit positions. When the damper is within a predetermined bump stop region near either of the compression and rebound limit positions, a bump stop value is determined and applied to the damper to provide a high minimum damping level creating an electronic bump stop for the damper.

Abstract: The invention provides a method and apparatus for controlling dampers in a suspension system of a vehicle body. A heave velocity of a vehicle body is derived from sensed dynamic variables of the vehicle body. A slew rate limit for a damping control command is derived in response to the heave velocity of the vehicle body. The damping control command for at least one dampers is generated in accordance with the slew rate limit.

Abstract: A suspension control for vehicle dampers uses a trimset value to compensate signals from relative body/wheel position sensors associated with the dampers. Each trimset value is determined by recording a sensor value with the body and wheel in a predetermined relative state, such as by lifting the vehicle until the associated wheel is free of the ground and hanging in a low limit position determined by the suspension apparatus. In vehicle operation, the trimset value is used as an offset to the relative position sensor signal to accurately determine damper position relative to its compression and rebound limit positions. When the damper is within a predetermined bump stop region near either of the compression and rebound limit positions, a bump stop value is determined and applied to the damper to provide a high minimum damping level creating an electronic bump stop for the damper. The high minimum damping level may be scaled downward as the damper moves away from its limit position.

Abstract: A method, system and computer readable medium storing a computer program is provided for independent control of a variable force damper system. The variable force damper system can be applied to control a vehicle suspension system. The system provides individual wheel control independent of vehicle body forces. In operation, at least one relative velocity signal and at least one body demand force is received. At least one body damper command is determined based on the body demand force. At least one wheel motion indicating parameter is determined based on the relative velocity signal. At least one wheel damper command is determined based on the wheel motion indicating parameter and a damper command is determined based on the larger of the body damper command and the wheel damper command.

Abstract: A vehicle suspension control stores, for each direction of vehicle lateral acceleration, a first set of enhanced vehicle damping commands that provide enhanced damping in compression for the suspension dampers on the outside of a turn and in rebound on the inside of the turn and a second set of enhanced body damping commands that provide enhanced damping in compression and rebound on both sides of the vehicle. Responsive to a sensed vehicle lateral acceleration, the control applies the first set of enhanced damping commands to the suspension dampers if a sensed steering angle is in the same direction as the sensed lateral acceleration and applies the second set of enhanced body damping commands to the suspension dampers if the sensed steering angle is in the opposite direction as the sensed lateral acceleration.

Abstract: A vehicle suspension control derives demand force commands from relative velocities of the suspension dampers at the corners of the vehicle and applies the demand force commands only when a force corresponding to the demand force command can be effectively exerted by the damper. The control is also responsive to a sensed vehicle handling event to derive a body control enhancement damping commands for selected suspension dampers and apply the body control enhancement damping commands without regard for the direction of demand force for the suspension dampers. Each body control enhancement damping command is derived from one or more measured vehicle dynamic variables associated with the sensed vehicle handling event and modified in magnitude in response to the direction and/or magnitude of the sensed relative velocity of damper to which the body control enhancement damping command is to be applied.

Abstract: A vehicle suspension control includes a vehicle body control responsive to body/wheel velocity at the corners of the vehicle body to derive a demand force command for dampers at each corner of the vehicle body for vehicle body control and applies each of the derived demand force commands to its respective damper only when a comparison of the direction of the demand force command with the sensed relative velocity of the damper indicates that a force corresponding to the demand force command can be effectively exerted by the damper. But the suspension control also includes a vehicle stability control responsive to an indicated vehicle lateral acceleration in a turn to determine, independently of the vehicle body control, a stability compression damping command for the suspension dampers on the side of the vehicle opposite the direction of the lateral acceleration and a stability rebound damping command for the suspension dampers on the side of the vehicle in the direction of the lateral acceleration.

Abstract: A vehicle suspension system is responsive to an active brake signal from a brake system indicating the application of a greater braking force to one front corner brake than to the other front corner brake to affect vehicle yaw rate. The vehicle suspension system determines the relative velocities of the front corner suspension adjacent the front corner brake receiving the greater braking force and the diagonally opposed rear corner suspension and further determines a compression damping command for the front corner suspension and a rebound damping command for the rear corner suspension. While the active brake signal is present, the suspension control applies the compression damping command for the front corner suspension when its relative velocity indicates that it is in compression. While the active brake signal is present, the suspension control also applies the rebound damping command for the rear corner suspension when its relative indicates that it is in rebound.

Abstract: In a vehicle with four corner suspensions, wherein during a transient turning maneuver, a body of the vehicle tends to compress two of the corner suspensions on a first side of the vehicle and expand two of the corner suspensions on a second side of the vehicle, wherein road inputs cause random compression and rebound of the four corner suspensions, a suspension control method comprising the steps of: sensing vehicle speed; monitoring steering wheel velocity; responsive to the vehicle speed and the steering wheel velocity, determining a signal indicative of a transient turning maneuver of the vehicle; responsive to the signal, determining compression damping commands for the two corner suspensions on the first side of the vehicle; responsive to the signal, determining rebound damping commands for the two corner suspensions on the second side of the vehicle; monitoring relative velocity of each corner suspension; applying the compression damping commands for the two corner suspensions on the first side of the

Abstract: In a first controller that runs a first control algorithm and a first interrupt service, wherein the first control algorithm includes a first series of commands repeatedly executed in sequence, wherein the first interrupt service performs a second series of commands when the first interrupt service is triggered, wherein the first controller includes a first free running counter with a counter timer value that repeatedly increments and resets when the counter timer overflows, a data communication method comprising the steps of: in each sequential execution of the first series of commands: reading a data signal to be transmitted; responsive to the data signal, computing an on-time; setting a first edge of a serial transmission signal; and loading a register with a value equal to a sum of the first counter value and the on time; independent of the first series of commands: comparing the first counter value to the register value; when the first counter value equals the register value, triggering the first interru