Active vehicle chassis dampening systems and methods

What is claimed is: 1. An active dampening system for a chassis of a vehicle having an engine, the system comprising: first and second linear force generators each being configured to generate vibrational force in two opposing directions; first and second adjustable damper brackets attached to first and second frame rails of the chassis, respectively, and configured to receive the first and second linear force generators, respectively, wherein the first and second adjustable damper brackets are each further configured to be rotatably adjusted between N different non-zero degree angles with respect to a vertical direction to select first and second angles for the first and second linear force generators, respectively, during a non-operational state of the vehicle and without adjusting an orientation of the chassis, wherein N is an integer greater than one; first and second accelerometers arranged on or proximate to the first and second frame rails, respectively, and configured to measure vibration of the first and second frame rails, respectively; and a controller configured to operate the engine in a cylinder deactivation mode during which at least some of a plurality of cylinders of the engine are deactivated and, during the cylinder deactivation mode: receive, from the first and second accelerometers, the measured vibrations of the first and second frame rails; generate control signals for the first and second linear force generators based on the measured vibration of the first and second frame rails, respectively; and output, to the first and second linear force generators, the control signals, wherein receipt of the control signals cause the first and second linear force generators to generate vibrational forces that at least partially dampen both lateral and vertical vibrations at the first and second frame rails, respectively, to decrease noise/vibration/harshness (NVH) such that an operational range of the cylinder deactivation mode can be extended to thereby increase a fuel economy of the vehicle. 2. The system of claim 1 , wherein N is five, and wherein the non-operational state of the vehicle is one of a vehicle build, a vehicle service, and a vehicle calibration event. 3. The system of claim 1 , wherein the first and second adjustable damper brackets are rotatably adjustable by a human operator. 4. The system of claim 1 , wherein the first and second adjustable damper brackets are rotatably adjustable by a machine. 5. A method of calibrating and controlling an active dampening system for a chassis of a vehicle having an engine, the method comprising: rotatably adjusting each of first and second adjustable damper brackets between one of N different non-zero degree angles with respect to a vertical direction during a non-operational state of the vehicle and without adjusting an orientation of the chasses, wherein the first and second adjustable damper brackets are attached to first and second frame rails of the chassis, respectively, and are configured to receive first and second linear force generators, respectively, and wherein N is an integer greater than one; after the adjusting, operating, by a controller, the engine in a cylinder deactivation mode during which at least some of a plurality of cylinders of the engine are deactivated and, during the cylinder deactivation mode; and during the cylinder deactivation mode: receiving, by the controller and from a first and second accelerometers, measured vibrations of the first and second frame rails, the first and second accelerometers being arranged on or proximate to the first and second frame rails, respectively; generating, by the controller, control signals for the first and second linear force generators based on the measured vibration of the first and second frame rails, respectively, the first and second linear force generators each being configured to generate vibrational force in two opposing directions; and outputting, by the controller and to the first and second linear force generators, the control signals, wherein receipt of the control signals cause the first and second linear force generators to generate vibrational forces that at least partially dampen both lateral and vertical vibrations at the first and second frame rails, respectively, to decrease noise/vibration/harshness (NVH) such that an operational range of the cylinder deactivation mode can be extended to thereby increase a fuel economy of the vehicle. 6. The method of claim 5 , wherein N is five, and wherein the non-operational state of the vehicle is one of a vehicle build, a vehicle service, and a vehicle calibration event. 7. The method of claim 5 , wherein the rotatable adjusting of the first and second adjustable damper brackets is performed by a human operator. 8. The method of claim 5 , wherein the rotatable adjusting of the first and second rotatable damper brackets is performed by a machine.