Suspension system with incremental roll and pitch stiffness control

What is claimed is: 1. A method of controlling a suspension system of a vehicle, comprising: connecting a manifold assembly to a plurality of dampers via a plurality of hydraulic circuits and a pump assembly via a pump hydraulic line, the manifold assembly including at least one manifold valve configured to control fluid flow between the pump hydraulic line and the plurality of hydraulic circuits, and the pump assembly including a pump that is arranged in fluid communication with the pump hydraulic line; setting a target stiffness and a target pressure in a suspension control unit (SCU) of the suspension system; monitoring real-time data from at least one onboard sensor or system, the real-time data including data reflecting at least one of fluid pressure within at least one of the hydraulic circuits, damper displacement for at least one of the dampers, lateral acceleration of the vehicle, and longitudinal acceleration of the vehicle; determining an effective stiffness of the suspension system based on the real-time data; determining if the effective stiffness of the suspension system is above or below the target stiffness; setting a new target pressure in the suspension control unit (SCU) if the effective stiffness is determined to be above or below the target stiffness by making a stepwise decrease or increase to the target pressure; opening the at least one manifold valve when the new target pressure is set by the suspension control unit (SCU); energizing the pump in a first direction or a second direction to pump hydraulic fluid into or out of the hydraulic circuits of the suspension system until the new target pressure is reached; closing the at least one manifold valve when the new target pressure is reached; and reiterating said steps of the method until the effective stiffness falls within a pre-determined range of the target stiffness. 2. The method as set forth in claim 1 , wherein said step of determining an effective stiffness of the suspension system based on the real-time data includes calculating an effective roll stiffness for the suspension system. 3. The method as set forth in claim 2 , further comprising the steps of: calculating a roll moment based on the fluid pressure monitored within at least one of the hydraulic circuits; calculating a roll angle based on the damper displacement monitored for at least one of the dampers; and calculating the effective roll stiffness by dividing the roll moment by the roll angle. 4. The method as set forth in claim 2 , further comprising the steps of: calculating a roll angle based on the damper displacement monitored for at least one of the dampers; and calculating the effective roll stiffness based on the roll angle and the lateral acceleration of the vehicle. 5. The method as set forth in claim 2 , further comprising the steps of: calculating a roll moment based on the fluid pressure monitored within at least one of the hydraulic circuits; and calculating the effective roll stiffness based on the roll moment and the lateral acceleration of the vehicle. 6. The method as set forth in claim 1 , wherein said step of determining an effective stiffness of the suspension system based on the real-time data includes calculating an effective pitch stiffness for the suspension system. 7. The method as set forth in claim 6 , further comprising the steps of: calculating a pitch moment based on the fluid pressure monitored within at least one of the hydraulic circuits; calculating a pitch angle based on the damper displacement monitored for at least one of the dampers; and calculating the effective pitch stiffness by dividing the pitch moment by the pitch angle. 8. The method as set forth in claim 6 , further comprising the steps of: calculating a pitch angle based on the damper displacement monitored for at least one of the dampers; and calculating the effective pitch stiffness based on the pitch angle and the longitudinal acceleration of the vehicle. 9. The method as set forth in claim 6 , further comprising the steps of: calculating a pitch moment based on the fluid pressure monitored within at least one of the hydraulic circuits; and calculating the effective pitch stiffness based on the pitch moment and the longitudinal acceleration of the vehicle. 10. A method of controlling a suspension system of a vehicle, comprising: connecting a manifold assembly to a plurality of dampers via a plurality of hydraulic circuits and a pump assembly via a pump hydraulic line, the manifold assembly including at least one manifold valve configured to control fluid flow between the pump hydraulic line and the plurality of hydraulic circuits, and the pump assembly including a pump that is arranged in fluid communication with the pump hydraulic line; setting a target roll stiffness, a target pitch stiffness, and a target pressure in a suspension control unit (SCU) of the suspension system; monitoring real-time data from at least one onboard sensor or system, the real-time data including data reflecting at least one of fluid pressure within at least one of the hydraulic circuits, damper displacement for at least one of the dampers, lateral acceleration of the vehicle, and longitudinal acceleration of the vehicle; determining an effective roll stiffness and an effective pitch stiffness of the suspension system based on the real-time data; determining if the effective roll stiffness is below the target roll stiffness and determining if the effective pitch stiffness is below the target pitch stiffness; setting a new target pressure in the suspension control unit (SCU) by making a stepwise increase to the target pressure if the effective roll stiffness is determined to be below the target roll stiffness or if the effective pitch stiffness is determined to be below the target pitch stiffness; opening the at least one manifold valve if the new target pressure is incremented by the suspension control unit (SCU) and energizing the pump in a first direction to pump hydraulic fluid into the hydraulic circuits of the suspension system until the new target pressure is reached; determining if the effective roll stiffness is above the target roll stiffness and determining if the effective pitch stiffness is above the target pitch stiffness; setting a new target pressure in the suspension control unit (SCU) by making a stepwise decrease to the target pressure if the effective roll stiffness is determined to be above the target roll stiffness or if the effective pitch stiffness is determined to be above the target pitch stiffness; opening the at least one manifold valve if the new target pressure is decremented by the suspension control unit (SCU) and energizing the pump in a second direction to pump hydraulic fluid out of the hydraulic circuits of the suspension system until the new target pressure is reached; closing the at least one manifold valve when the new target pressure is reached; and reiterating said steps of the method until the effective roll stiffness and the effective pitch stiffness fall within a pre-determined range of the target roll stiffness and the target pitch stiffness. 11. The method as set forth in claim 10 , further comprising the steps of: calculating a roll moment based on the fluid pressure monitored within at least one of the hydraulic circuits; calculating a roll angle based on the damper displacement monitored for at least one of the dampers; and calculating the effective roll stiffness by dividing the roll moment by the roll angle. 12. The method as set forth in claim 10 , further comprising the steps of: calculating a roll angle based on the damper displacement monitored for at