Axle-shaft system with two-stage stiffness and side-to-side stiffness bias

The invention claimed is: 1. An axle-shaft system for transmitting an input torque in a drive-train of a motor vehicle, the axle-shaft system comprising: a first two-stage stiffness axle-shaft and a second two-stage stiffness axle-shaft; wherein each of the first two-stage stiffness axle-shaft and the second two-stage stiffness axle-shaft includes: a hollow cylinder defined by a longitudinal axis, a first end, and a distal second end, and having a hollow cylinder stiffness; and an inner shaft extending through the hollow cylinder along the longitudinal axis and defined by a first end, and a distal second end, and having an inner shaft stiffness; wherein each of the first two-stage stiffness axle-shaft and the second two-stage stiffness axle-shaft is constructed such that: the first end of the respective inner shaft is engaged with the first end of the respective hollow cylinder via a rotational clearance fit; the second end of the respective inner shaft is rotationally fixed to the second end of the respective hollow cylinder such that the first end of the inner shaft will twist to a predetermined angle with respect to the second end of the inner shaft in response to the input torque; and the inner shaft stiffness defines a first-stage stiffness of the axle-shaft and the inner shaft stiffness together with the hollow cylinder stiffness defines a second-stage stiffness of the axle-shaft; and wherein at least one of the first-stage stiffness and the second-stage stiffness of the first axle-shaft is dissimilar from the respective one of the first-stage stiffness and the second-stage stiffness of the second axle-shaft. 2. The two-stage stiffness axle-shaft system of claim 1 , wherein the stiffness of the first inner shaft is dissimilar from the stiffness of the second inner shaft. 3. The two-stage stiffness axle-shaft system of claim 1 , wherein the stiffness of the first hollow cylinder is dissimilar from the stiffness of the second hollow cylinder. 4. The two-stage stiffness axle-shaft system of claim 1 , wherein at least one of the first two-stage stiffness axle-shaft and the second two-stage stiffness axle-shaft also includes a first damping element arranged between the inner shaft and the hollow cylinder and configured to control variation in the input torque transmitted by the axle-shaft via generated damping, and wherein the first damping element is configured to generate a gradual transition between the first-stage stiffness and the second-stage stiffness. 5. The two-stage stiffness axle-shaft system of claim 4 , wherein when each of the first two-stage stiffness axle-shaft and the second two-stage stiffness axle-shaft includes the respective first damping element, the damping generated by the first damping element of the first inner shaft is dissimilar from the damping generated by the first damping element of the second inner shaft. 6. The two-stage stiffness axle-shaft system of claim 4 , wherein at least one of the first two-stage stiffness axle-shaft and the second two-stage stiffness axle-shaft is constructed such that: the first end of the inner shaft includes a first outer spline and the first end of the hollow cylinder includes a first inner spline; and the first outer spline is engaged with the first inner spline via the rotational clearance fit at a first interface. 7. The two-stage stiffness axle-shaft system of claim 6 , wherein: at least one of the first two-stage stiffness axle-shaft and the second two-stage stiffness axle-shaft also includes a second damping element arranged between the first outer spline and the first inner spline; and the second damping element is an elastomer component occupying the rotational clearance fit and configured to control variation in the input torque transmitted by the axle-shaft at the first interface via generated damping. 8. The two-stage stiffness axle-shaft system of claim 7 , wherein when each of the first two-stage stiffness axle-shaft and the second two-stage stiffness axle-shaft includes the respective second damping element, the damping generated by the second damping element of the first inner shaft is dissimilar from the damping generated by the second damping element of the second inner shaft. 9. The two-stage stiffness axle-shaft system of claim 4 , wherein at least one of the first two-stage stiffness axle-shaft and the second two-stage stiffness axle-shaft is constructed such that: the second end of the inner shaft includes a second outer spline and the second end of the hollow cylinder includes a second inner spline; and the second outer spline is press-fit into the second inner spline at a second interface. 10. The two-stage stiffness axle-shaft of claim 1 , wherein at least one of the first two-stage stiffness axle-shaft and the second two-stage stiffness axle-shaft is constructed such that the second end of the inner shaft is welded to the second end of the hollow cylinder. 11. A drive-train for a motor vehicle comprising: a power-plant configured to generate torque; a first road wheel and a second road wheel; a differential configured to receive the torque from the power-plant; and an axle-shaft system operatively connected to and configured to transmit the torque from the differential to the first and second road wheels, the axle-shaft system including: a first two-stage stiffness axle-shaft configured to transmit a portion of the torque to the first road wheel and a second two-stage stiffness axle-shaft configured to transmit another portion of the torque to the second road wheel; wherein each of the first two-stage stiffness axle-shaft and the second two-stage stiffness axle-shaft includes: a hollow cylinder defined by a longitudinal axis, a first end, a distal second end, and having a hollow cylinder stiffness; and an inner shaft extending through the hollow cylinder along the longitudinal axis and defined by a first end, a distal second end, and having an inner shaft stiffness; wherein each of the first two-stage stiffness axle-shaft and the second two-stage stiffness axle-shaft is constructed such that: the first end of the respective inner shaft is engaged with the first end of the respective hollow cylinder via a rotational clearance fit; the second end of the respective inner shaft is rotationally fixed to the second end of the respective hollow cylinder such that the first end of the inner shaft will twist to a predetermined angle with respect to the second end of the inner shaft in response to the input torque; and the inner shaft stiffness defines a first-stage stiffness of the axle-shaft and the inner shaft stiffness together with the hollow cylinder stiffness defines a second-stage stiffness of the axle-shaft; and wherein at least one of the first-stage stiffness and the second-stage stiffness of the first axle-shaft is dissimilar from the respective one of the first-stage stiffness and the second-stage stiffness of the second axle-shaft. 12. The drive-train of claim 11 , wherein the stiffness of the first inner shaft is dissimilar from the stiffness of the second inner shaft. 13. The drive-train of claim 11 , wherein the stiffness of the first hollow cylinder is dissimilar from the stiffness of the second hollow cylinder. 14. The drive-train of claim 11 , wherein at least one of the first two-stage stiffness axle-shaft and the second two-stage stiffness axle-shaft also includes a first damping element arranged between the inner shaft and the hollow cylinder and configured to control variation in the input torque transmitted by the axle-shaft via generated damping, and wherein the first damping element is configured t