Abstract: A system and method for controlling a damping system. The system has at least two dampers for damping between sprung and unsprung masses in the compression and rebound directions. Sensors generate signals based on position and other parameters of motion representative of the displacement between the sprung and unsprung masses. The process determines the appropriate compression and rebound forces to be applied at the wheels. A regulator responds to at least one of the independent compression and rebound control signals for adjusting, respectively, at least one of compression and rebound resisting forces of the dampers between the masses. Compliance for the dampers is emulated with software to produce the desired compliance forces.

Abstract: A suspension control unit as well as a control valve for such unit are provided which are incorporated in a computerized suspension system which automatically and continuously monitors and control's a vehicle's ride performance. The suspension control unit is composed of an actuator and a fluid control unit. A valve is coupled to the actuator for controlling the fluid pressure within the actuator. The valve has an annular body having a side inlet passage and an outlet opening in communication with the reservoir. A poppet driven by a solenoid is slideably fitted within the body wherein the poppet can slide between a first position blocking flow to the outlet opening and a second position not blocking the flow to the outlet opening. The poppet has a shoulder that is exposed to the inlet. Fluid pressure to the inlet of the valve acts on the differential area of the poppet to produce an poppet retracting force which is opposed by the force of an electrically adjustable solenoid.