Wide bandwidth circular force generator devices, systems, and methods

What is claimed is: 1. A circular force generator comprising: a first rotor assembly comprising: a first spinning bearing mounted about a shaft at a first position; and a first eccentric mass extending in a first axial direction away from the first position; and a second rotor assembly comprising: a second spinning bearing mounted about the shaft at a second position that is spaced apart in the first axial direction from the first position; and a second eccentric mass extending in a second axial direction away from the second position, wherein the second axial direction is opposite the first axial direction; wherein the first eccentric mass and the second eccentric mass are each rotatable about the shaft to generate a combined rotating force; wherein a first phase-shifting bearing is connected to the first eccentric mass and is rotatably coupled to the second rotor assembly at or near the second position; wherein a second phase-shifting bearing is connected to the second eccentric mass and is rotatably coupled to the first rotor assembly at or near the first position; wherein the first phase-shifting bearing and the second phase-shifting bearing allow relative rotation between the first eccentric mass and the second eccentric mass; and wherein a relative angular position between the first eccentric mass and the second eccentric mass is selectively adjustable to change a magnitude and a phase of the combined rotating force. 2. The circular force generator of claim 1 , wherein a first center of mass of the first eccentric mass rotates in a first path about the shaft, wherein a second center of mass of the second eccentric mass rotates in a second path about the shaft, and wherein the first path and the second path are substantially coplanar. 3. The circular force generator of claim 1 comprising: a first motor coupled to the first rotor assembly and configured to drive rotation of the first eccentric mass about the shaft; and a second motor coupled to the second rotor assembly and configured to drive rotation of the second eccentric mass about the shaft. 4. The circular force generator of claim 3 , wherein the first motor comprises a first frameless annular motor coupled to the first rotor assembly; wherein the first rotor assembly comprises a first position sensor in communication with the first rotor assembly and configured to identify a position of the first eccentric mass with respect to the shaft; wherein the second motor comprises a second frameless annular motor coupled to the second rotor assembly; and wherein the second rotor assembly comprises a second position sensor in communication with the second rotor assembly and configured to identify a position of the second eccentric mass with respect to the shaft. 5. The circular force generator of claim 1 wherein the second rotor assembly has a shape and configuration that is identical to a shape and configuration of the first rotor assembly. 6. A circular force generator comprising: a first rotor assembly comprising: a first spinning bearing mounted about a shaft at a first position; a first eccentric mass extending in a first axial direction away from the first position; and a first phase-shifting bearing connected to the first eccentric mass at a second position that is spaced apart in the first axial direction from the first position; and a second rotor assembly comprising: a second spinning bearing mounted about the shaft at or near the second position and rotatably coupled to the first phase-shifting bearing; a second eccentric mass extending in a second axial direction away from the second position, wherein the second axial direction is opposite the first axial direction; and a second phase-shifting bearing connected to the second eccentric mass and rotatably coupled to the first spinning bearing at or near the first position; wherein the first eccentric mass and the second eccentric mass are each rotatable about the shaft to generate a combined rotating force; wherein a first center of mass of the first eccentric mass rotates in a first path about the shaft, wherein a second center of mass of the second eccentric mass rotates in a second path about the shaft, and wherein the first path and the second path are substantially coplanar; and wherein the first phase-shifting bearing and the second phase-shifting bearing allow for selective adjustment of a relative angular position between the first eccentric mass and the second eccentric mass to change a magnitude and a phase of the combined rotating force. 7. The circular force generator of claim 6 comprising: a first motor coupled to the first rotor assembly and configured to drive rotation of the first eccentric mass about the shaft; and a second motor coupled to the second rotor assembly and configured to drive rotation of the second eccentric mass about the shaft. 8. The circular force generator of claim 7 , wherein the first motor comprises a first frameless annular motor coupled to the first rotor assembly; wherein the first rotor assembly comprises a first position sensor in communication with the first rotor assembly and configured to identify a position of the first eccentric mass with respect to the shaft; wherein the second motor comprises a second frameless annular motor coupled to the second rotor assembly; and wherein the second rotor assembly comprises a second position sensor in communication with the second rotor assembly and configured to identify a position of the second eccentric mass with respect to the shaft. 9. The circular force generator of claim 6 wherein the second rotor assembly has a shape and configuration that is identical to a shape and configuration of the first rotor assembly. 10. A method of generating a circular force, the method comprising: mounting a first rotor assembly about a shaft, the first rotor assembly comprising: a first spinning bearing mounted about the shaft at a first position; and a first eccentric mass extending in a first axial direction away from the first position; mounting a second rotor assembly about the shaft, the second rotor assembly comprising: a second spinning bearing mounted about the shaft at a second position that is spaced apart in the first axial direction from the first position; and a second eccentric mass extending in a second axial direction away from the second position, wherein the second axial direction is opposite the first axial direction; rotating the first eccentric mass and the second eccentric mass about the shaft to generate a combined rotating force; and adjusting a relative angular position between the first eccentric mass and the second eccentric mass to change a magnitude and a phase of the combined rotating force; wherein mounting the first rotor assembly to the shaft comprises rotatably coupling a first phase-shifting bearing that is connected to the first eccentric mass to the second rotor assembly at or near the second position; wherein mounting the second rotor assembly to the shaft comprises rotatably coupling a second phase-shifting bearing that is connected to the second eccentric mass to the first rotor assembly at or near the first position; and wherein the first phase-shifting bearing and the second phase-shifting bearing allow relative rotation between the first eccentric mass and the second eccentric mass. 11. The method of claim 10 , wherein a first center of mass of the first eccentric mass rotates in a first path about the shaft, wherein a second center of mass of the second eccentric mass rotates in a second path about the shaft, and wherein the first path and the second path are substantially coplanar.