Eccentrically piloted hydraulic commutator

What is claimed is: 1. A hydraulic motor comprising: a rotor that is connected to a shaft that rotates about a first axis; a stator having a central axis that is a second axis different from the first axis, wherein the rotor and the stator define a plurality of motor pockets for receiving a flow of hydraulic fluid, and the rotor is configured to rotate relative to the stator based on a pressure differential between the motor pockets; and a commutator having porting configured to control the flow of hydraulic fluid into the motor pockets; wherein the rotor is configured to rotate about the first axis by rotation of the shaft and the stator is configured to rotate about the second axis in response to the pressure differential, and the stator is configured to orbit within an outer housing ring in response to the pressure differential such that the second axis orbits about the first axis; and wherein the shaft extends through the commutator through a shaft space that is eccentrically positioned through the commutator such that the commutator is eccentrically piloted about the first axis and the second axis by rotation of the shaft so that the commutator both rotates and orbits to control the flow of hydraulic fluid into the motor pockets. 2. The hydraulic motor of claim 1 , further comprising an orbiting ring that is longitudinally fixed to the stator and radially fixed to the commutator, and a portion of the commutator extends longitudinally from the orbiting ring opposite to the stator. 3. The hydraulic motor of claim 2 , wherein the stator, orbiting ring, and commutator comprise an orbiting assembly, and the housing ring defines an orbiting space in which the orbiting assembly orbits about the first axis. 4. The hydraulic motor of claim 1 , wherein the rotor has a plurality of lobes and the stator has a plurality of vanes, and as the rotor rotates the lobes and vanes successively form the motor pockets for receipt and expulsion of the hydraulic fluid. 5. The hydraulic motor of claim 1 , wherein the porting of the commutator comprises an inner commutator port configured to supply hydraulic fluid to the motor pockets at a first pressure, and an outer commutator port configured to supply hydraulic fluid to the motor pockets at a second pressure different from the first pressure to create the pressure differential between the motor pockets. 6. The hydraulic motor of claim 5 , wherein a fluid pathway through the inner commutator port is isolated from a fluid pathway through the outer commutator port. 7. The hydraulic motor of claim 5 , wherein the inner and outer commutator ports are shaped as kidney ports. 8. The hydraulic motor of claim 5 , wherein the inner commutator port extends through an entire longitudinal thickness of the commutator. 9. The hydraulic motor of claim 8 , wherein the outer commutator port extends partially through the longitudinal thickness of the commutator, and the commutator has a slot that forms a fluid pathway between the outer commutator port and an outer diameter of the commutator. 10. The hydraulic motor of claim 9 , further comprising: an orbiting ring that is longitudinally fixed to the stator and radially fixed to the commutator, and a portion of the commutator extends longitudinally from the orbiting ring opposite to the stator; and an outer housing ring; wherein the stator, orbiting ring, and commutator comprise an orbiting assembly, and the housing ring defines an orbiting space in which the orbiting assembly orbits about the first axis; and wherein the slot forms a fluid pathway between the outer commutator port and the orbiting space. 11. The hydraulic motor of claim 5 , wherein the commutator further defines a shaft space configured to receive an output shaft, and the shaft space is eccentrically positioned through the commutator. 12. The hydraulic motor of claim 5 , further comprising a motor housing defining a first inlet configured to supply hydraulic fluid at the first pressure to the inner commutator port, and defining a second inlet configured to supply hydraulic fluid at the second pressure to the outer commutator port. 13. The hydraulic motor of claim 12 , wherein the first inlet includes an inner ring port in fluid communication with the inner commutator port, and the second inlet includes an outer ring port in fluid communication with the outer commutator port. 14. The hydraulic motor of claim 5 , wherein when the first pressure is a low pressure relative to the second pressure, the rotor is configured to rotate in a forward direction, and when the first pressure is a high pressure relative to the second pressure, the rotor is configured to rotate in a reverse direction. 15. The hydraulic motor of claim 1 , wherein the commutator is configured to be piloted on an inner diameter by the first axis, and to be piloted on its outer diameter by the second axis. 16. The hydraulic motor of claim 1 , further comprising an output shaft that is configured to be driven by the rotation of the rotor, wherein the output shaft is configured to be driven by the rotation of the rotor to rotate about the first axis without orbiting. 17. A commutator configured to control a flow of hydraulic fluid through a hydraulic motor, the commutator comprising: porting configured to control the flow of hydraulic fluid, wherein the commutator defines a shaft space for receiving a shaft, the shaft space being eccentrically positioned through the commutator so that the commutator is eccentrically piloted about a first axis and a second axis different from the first axis by rotation of the shaft so that the commutator both rotates and orbits to control the flow of hydraulic fluid. 18. The commutator of claim 17 , wherein the porting comprises an inner commutator port configured to supply hydraulic fluid to motor pockets of the hydraulic motor at a first pressure, and an outer commutator port configured to supply hydraulic fluid to the motor pockets at a second pressure different from the first pressure to create a pressure differential between the motor pockets. 19. The commutator of claim 18 , wherein a fluid pathway through the inner commutator port is isolated from a fluid pathway through the outer commutator port. 20. The commutator of claim 18 , wherein the inner commutator port extends through an entire longitudinal thickness of the commutator; and the outer commutator port extends partially through the longitudinal thickness of the commutator, and the commutator has a slot that forms a fluid pathway between the outer commutator port and an outer diameter of the commutator.