Robot for use with orthopaedic inserts

We claim: 1. A surgical system comprising: an orthopaedic insert having at least one predrilled hole for attaching said insert to a bone; a drill guiding plate carried by a robot which is mounted in a fixed position relative to said bone, said guiding plate having at least one hole to enable guiding a drill into said bone and through said at least one predrilled hole; and a control system which utilizes data from at least one image generated during said surgery to instruct said robot to align the axis of said at least one hole defined by said drill guiding plate essentially colinearly with the axis of said at least one predrilled hole defined by said insert. 2. A surgical system according to claim 1 wherein said drill guiding plate comprises a plurality of fiducial markers disposed in a predetermined pattern, to enable said robot to align said drill guiding plate into a fronto-parallel orientation in said at least one image. 3. A surgical system according to claim 1 , wherein said at least one image is generated at an alignment such that said at least one target hole has a minimum elliptic shape in said at least one image. 4. A surgical system according to claim 1 , and wherein said at least one image is generated at an alignment such that said at least one predrilled hole is imaged in a fronto-parallel orientation. 5. A surgical system according to claim 1 , and wherein said at least one image is generated at an alignment such that said at least one predrilled hole has a minimum elliptic shape in said at least one image. 6. A surgical system according to claim 1 and wherein said control system aligns said guiding plate by utilizing data from only one image of said imaging system. 7. A surgical system according to claim 1 and wherein said robot is mounted either directly on said bone or is attached to said insert associated with said bone. 8. A surgical system according to claim 1 and wherein said robot maintains its position relative to said bone such that tracking of said bone position or immobilization of said bone is obviated. 9. A surgical system according to claim 1 and wherein said bone is a long bone, and said orthopaedic insert is an intramedullary nail, and said at least one predrilled hole is a distal locking hole. 10. A surgical system according to claim 9 and wherein said robot is attached either directly to said bone or to the proximal end of said intramedullary nail. 11. A surgical system according to claim 1 and wherein said orthopaedic insert is an externally attached connector plate, and said at least one predrilled hole is a connecting hole. 12. A surgical system according to claim 11 and wherein said bone is a femur, and said connector plate is a percutaneous compression plate, and said connecting hole accommodates a screw for connecting said plate to the shaft of said femur or a fractured head of said femur to its shaft. 13. A surgical system comprising: an orthopaedic insert having at least one predrilled hole for attaching said insert to a bone; a drill guiding plate having a plurality of fiducial markers disposed in a predetermined pattern, and attached to a robot which is mounted in a fixed position relative to said bone, said guiding plate having at least one hole for guiding a drill into said bone and through said at least one predrilled hole; and a control system which utilizes data obtained from the positions of at least some of said plurality of fiducial markers in at least one image generated during said surgery, to instruct said robot to align said drill guiding plate in a fronto-parallel orientation. 14. A surgical system according to claim 13 , and wherein said at least one image is generated at an alignment such that said at least one predrilled hole is imaged in a fronto-parallel orientation. 15. A surgical system according to claim 13 , wherein said control system is further configured to utilize data obtained from said at least one image to instruct said robot to align the axis of said at least one hole defined by said drill guiding plate essentially colinearly with the axis of said at least one predrilled hole defined by said insert. 16. A surgical system according to claim 13 , wherein said at least one image is generated at an alignment such that said at least one predrilled hole has a minimum elliptic shape in said at least one image. 17. A surgical system according to claim 13 , wherein said at least one image is generated at an alignment such that said at least one target hole has a minimum elliptic shape in said at least one image. 18. A surgical system according to claim 13 , wherein said robot is mounted either directly on said bone or is attached to said insert associated with said bone. 19. A surgical system according to claim 13 and wherein said robot maintains its position relative to said bone such that tracking of said bone position or immobilization of said bone is obviated. 20. A surgical system according to claim 13 , wherein said control system is further configured to utilize data obtained from said at least one image to instruct said robot to translate said target guide laterally so that the positions in said at least one image of the axes of at least one hole for guiding a drill and of at least one predrilled hole coincide.