Robotic alignment of a tool or pin with a virtual plane

The invention claimed is: 1. A surgical system for inserting a pin in a bone coincident with a virtual plane having a predetermined location relative to the bone, comprising: a robotic surgical device for aligning or maintaining alignment of the pin coincident with the virtual plane in response to control signals; and a computer operating software from a non-transitory memory and configured to receive inputs comprising the predetermined location of the virtual plane and a location of at least one of the bone and the robotic surgical device, wherein the computer comprises a processor configured to generate the control signals using the inputs. 2. The surgical system of claim 1 wherein the robotic surgical device comprises the computer. 3. The surgical system of claim 1 wherein the computer is separate from the robotic surgical device. 4. The surgical system of claim 1 wherein the input corresponding to the location of the robotic surgical device is an input corresponding to a position and orientation (POSE) of at least a portion of the robotic surgical device comprising at least one of: i) the pin; or ii) a set of fiducial markers coupled to the robotic surgical device. 5. The surgical system of claim 1 wherein the input corresponding to the location of at least one of the bone and the surgical device is received from a tracking system. 6. The surgical system of claim 1 further comprising a tracking system, the pin, or a combination thereof. 7. The surgical system of claim 1 wherein the computer is configured to wirelessly receives the inputs. 8. The surgical system of claim 1 wherein the predetermined location of the virtual plane is oriented with respect to a predetermined location for a cut surface to be created on the bone. 9. The surgical system of claim 8 wherein the virtual plane orientation is offset by a predetermined distance from the predetermined location for the cut surface. 10. The surgical system of claim 9 wherein the predetermined distance is based at least in part on a geometry of a cutting guide. 11. The surgical system of claim 1 wherein the robotic surgical device comprises at least one of: a hand-held robotic device; a serial-chain robotic device; a parallel robotic device; or a master-slave robotic device. 12. The surgical system of claim 1 wherein the robotic surgical device is controlled autonomously, semi-autonomously, haptically, or a combination thereof. 13. The surgical system of claim 1 wherein the robotic surgical device is a hand-held robotic device comprising: a hand-held portion; a working portion movably connected to the hand-held portion; a motor for driving the pin for insertion of the pin in the bone; and an actuator system for moving the working portion relative to the hand-held portion in response to the control signals. 14. The surgical system of claim 1 wherein the bone is subject to knee arthroplasty. 15. A surgical system for forming a pilot hole in a bone for receiving a pin, wherein the pilot hole is formed coincident with a virtual plane having a predetermined location relative to the bone, comprising: a robotic surgical device for aligning or maintaining alignment of a tool coincident with the virtual plane in response to control signals, wherein the tool is configured to form a pilot hole in the bone for receiving a pin in the pilot hole; and a computer operating software from a non-transitory memory and configured to receive inputs comprising the predetermined location of the virtual plane and a location of at least one of the bone and the robotic surgical device, wherein the computer comprises a processor configured to generate the control signals using the inputs. 16. The surgical system of claim 15 wherein the robotic surgical device comprises the computer. 17. The surgical system of claim 15 wherein the computer is separate from the robotic surgical device. 18. The surgical system of claim 15 wherein the input corresponding to the location of the robotic surgical device is an input corresponding to a position and orientation (POSE) of at least a portion of the robotic surgical device comprising at least one of: i) the tool; or ii) a set of fiducial markers coupled to the robotic surgical device. 19. The surgical system of claim 15 wherein the input corresponding to the location of at least one of the bone and the surgical device is received from a tracking system. 20. The surgical system of claim 15 further comprising a tracking system, the tool, or a combination thereof. 21. The surgical system of claim 16 wherein the computer is configured to wirelessly receives the inputs. 22. The surgical system of claim 15 wherein the predetermined location of the virtual plane is oriented with respect to a predetermined location for a cut surface to be created on the bone. 23. The surgical system of claim 22 wherein the virtual plane orientation is offset by a predetermined distance from the predetermined location for the cut surface. 24. The surgical system of claim 23 wherein the predetermined distance is based at least in part on a geometry of a cutting guide. 25. The surgical system of claim 15 wherein the robotic surgical device comprises at least one of: a hand-held robotic device; a serial-chain robotic device; a parallel robotic device; or a master-slave robotic device. 26. The surgical system of claim 15 wherein the robotic surgical device is controlled autonomously, semi-autonomously, haptically, or a combination thereof. 27. The surgical system of claim 15 wherein the robotic surgical device is a hand-held robotic device comprising: a hand-held portion; a working portion movably connected to the hand-held portion; a motor for driving the pin for insertion of the pin in the bone; and an actuator system for moving the working portion relative to the hand-held portion in response to the control signals. 28. The surgical system of claim 15 wherein the bone is subject to knee arthroplasty.