Regeneration strategy for a vehicle having decoupled front and rear axle drive actuators

The invention claimed is: 1. A method of controlling a vehicle having a first axle driven by an internal combustion engine, a second axle driven by a second power source, and an energy storage device, wherein the internal combustion engine and the second power source are mechanically independent of each other and do not directly communicate torque to each other, the method comprising: sensing a position of an accelerator pedal to determine if the accelerator pedal is in a depressed position, or if the accelerator pedal is in a non-depressed position; sensing a position of a brake pedal to determine if the brake pedal is in a depressed position, or if the brake pedal is in a non-depressed position; selecting an axle control strategy, with a vehicle controller, to control energy regeneration of the energy storage device based on the position of the accelerator pedal being either the depressed position or the non-depressed position, and the position of the brake pedal being either the depressed position or the non-depressed position; sending a control signal from the vehicle controller to at least one vehicle component to implement the selected axle control strategy; determining at least one vehicle parameter, wherein the at least one vehicle parameter includes one of: a driver desired acceleration, a driver desired deceleration, an actual torque of the internal combustion engine, a regeneration torque request, a first axle propulsive torque, a second axle propulsive torque, a state of charge dependent region, a left side first axle friction brake torque, a right side first axle friction brake torque, a left side second axle friction brake torque, a right side second axle friction brake torque, and a modified wheel torque target; and blocking regeneration of the energy storage device when the accelerator pedal is disposed in the depressed position, the brake pedal is disposed in the non-depressed position, and the state of charge dependent region is not set to a fourth region, wherein the fourth region is a user selected region that enables regeneration of the energy storage device during forward acceleration of the vehicle, lateral acceleration of the vehicle, or deceleration of the vehicle. 2. The method set forth in claim 1 , further comprising blocking regeneration of the energy storage device when the accelerator pedal is disposed in the depressed position, the brake pedal is disposed in the non-depressed position, the state of charge dependent region is set to a fourth region, and current operating dynamics of the vehicle are not currently within the fourth region, wherein the fourth region is a user selected region that enables regeneration of the energy storage device during forward acceleration of the vehicle, lateral acceleration of the vehicle, or deceleration of the vehicle. 3. The method set forth in claim 1 , wherein selecting the axle control strategy includes selecting the axle control strategy that dedicates the second axle for regeneration of the energy storage device, and dedicates the first axle for propulsion of the vehicle, when the accelerator pedal is disposed in the depressed position, the brake pedal is disposed in the non-depressed position, the state of charge dependent region is set to a fourth region, and current operating dynamics of the vehicle are currently within the fourth region, wherein the fourth region is a user selected region that enables regeneration of the energy storage device during forward acceleration of the vehicle, lateral acceleration of the vehicle, or deceleration of the vehicle. 4. The method set forth in claim 1 , wherein selecting the axle control strategy includes selecting the axle control strategy that controls the second axle for both regeneration of the energy storage device and friction braking to slow the vehicle, and controls the first axle for friction braking to slow the vehicle and provide a drag torque to slow a rotational speed of the internal combustion engine, when the accelerator pedal is disposed in the non-depressed position, the brake pedal is disposed in the depressed position, and either a numerical difference between the left first axle friction brake torque minus the regeneration torque request is greater than zero or a numerical difference between the right first axle friction brake torque and the regeneration torque request is greater than zero. 5. The method set forth in claim 1 , wherein selecting the axle control strategy includes selecting the axle control strategy that dedicates the second axle for regeneration of the energy storage device, controls the first axle to provide no friction braking, and controls the internal combustion engine to reduce the actual torque of the internal combustion engine by the modified wheel torque target, when the accelerator pedal is disposed in the non-depressed position, the brake pedal is disposed in the depressed position, both a numerical difference between the left first axle friction brake torque minus the regeneration torque request and a numerical difference between the right first axle friction brake torque and the regeneration torque request are less than zero, and either a numerical summation of the left first axle friction brake torque plus the actual torque of the internal combustion engine is less than zero or a numerical summation of the right first axle friction brake torque plus the actual torque of the internal combustion engine is less than zero. 6. The method set forth in claim 1 , wherein selecting the axle control strategy includes selecting the axle control strategy that dedicates the second axle for regeneration of the energy storage device, controls the first axle to provide friction braking to slow the vehicle, and controls the first axle to provide drag torque to slow a rotational speed of the internal combustion engine, when the accelerator pedal is disposed in the non-depressed position, the brake pedal is disposed in the depressed position, both a numerical difference between the left first axle friction brake torque minus the regeneration torque request and a numerical difference between the right first axle friction brake torque and the regeneration torque request are less than zero, and both a numerical summation of the left first axle friction brake torque plus the actual torque of the internal combustion engine and a numerical summation of the right first axle friction brake torque plus the actual torque of the internal combustion engine are equal to or greater than zero. 7. The method set forth in claim 1 , wherein selecting the axle control strategy includes selecting a strategy that offsets the second axle propulsive torque by the modified wheel torque target, and offsets the first axle propulsive torque by the modified wheel torque target, when the accelerator pedal is disposed in the depressed position, the brake pedal is disposed in the depressed position, the driver's desired deceleration is not greater than the driver's desired acceleration, and either a numerical difference between the left first axle friction brake torque minus the second axle propulsive torque is less than zero or a numerical difference between the right first axle friction brake torque minus the second axle propulsion torque is less than zero. 8. The method set forth in claim 1 , wherein selecting the axle control strategy includes selecting a strategy that reduces the second axle propulsive torque by friction, including all or part of the modified wheel torque target, and controls the first axle to reduce the friction torque of the first axle and provide the propulsive torque necessary to achieve the driver's desired acceleration, when the accelerator pedal is disposed in the depressed position, the brake pedal is disposed in the depressed position, t