Apparatus and method for customized shaping of orthodontic archwires and other medical devices

We claim: 1. A method of calibrating a bending apparatus comprising at least a first moveable manipulator and at least a second moveable manipulator, comprising the steps of: positioning a wire such that it is held by a first gripper of the first moveable manipulator and a second gripper of the second moveable manipulator, wherein the first moveable manipulator includes one revolute joint defining a first rotation axis and three prismatic joints defining a first translation axis, a second translation axis, and a third translation axis with the one revolute joint and the three prismatic joints mechanically linked together with the first gripper located at an end of the linked joints of the first moveable manipulator and wherein the second moveable manipulator includes two revolute joints defining a second rotation axis and a third rotation axis with the two revolute joints mechanically linked together with the second gripper located at an end of the linked joints of the second moveable manipulator; moving the first rotation axis, included as part of the first moveable manipulator, measuring a movement of the first gripper from moving the first rotation axis, measuring a first resulting movement of the wire from moving the first rotation axis, and recording the first resulting movement; moving the second rotation axis, included as part of the second moveable manipulator, measuring a movement of the second gripper from moving the second rotation axis, measuring a second resulting movement of the wire from moving the second rotation axis, and recording the second resulting movement; moving the first translation axis, included as part of the first moveable manipulator, measuring a movement of the first gripper from moving the first translation axis, measuring a third resulting movement of the wire from moving the first translation axis, and recording the third resulting movement; moving the third rotation axis, included as part of the second moveable manipulator, measuring a movement of the second gripper fro moving the third rotation axis, measuring a fourth resulting movement of the wire from moving the third rotation axis, and recording the fourth resulting movement; moving the second translation axis, included as part of the first moveable manipulator, measuring a movement of the first gripper from moving the second translation axis, measuring a fifth resulting movement of the wire from moving the second translation axis, and recording the fifth resulting movement; moving the third translation axis, included as part of the first moveable manipulator, measuring a movement of the first gripper moving the third translation axis, measuring a sixth resulting movement of the wire from moving the third translation axis, and recording the sixth resulting movement; and developing a real model based on the movements of the axes of the first moveable manipulator and the second moveable manipulator and the corresponding recorded movements of the wire, wherein each of the axes of the first moveable manipulator and the second moveable manipulator are moved in different directions. 2. The method of claim 1 , wherein the resulting movements of the wire are measured by a vision system. 3. The method of claim 2 , wherein the vision system is configured to measure single bends in the wire as soon as they are made. 4. The method of claim 2 , further comprising iteratively bending and measuring bends in the wire until correct over-bending values are found. 5. A method of calibrating a bending apparatus comprising at least a first moveable manipulator and at least a second moveable manipulator, comprising the steps of: positioning a wire such that it is held by a first gripper of the first moveable manipulator and a second gripper of the second moveable manipulator, wherein the first moveable manipulator includes at least one revolute joint defining a first rotation axis and at least one prismatic joint defining a first translation axis with the at least one revolute joint and the at least one prismatic joint mechanically linked together with the first gripper located at an end of the linked joints of the first moveable manipulator, and wherein the second moveable manipulator includes at least two revolute joints defining a second rotation axis and a third rotational axis with the at least two revolute joints mechanically linked together with the second gripper located at an end of the linked joints of the second moveable manipulator; moving the first rotation axis, included as part of the first moveable manipulator, measuring a movement of the first gripper from moving the first translation axis, measuring a first resulting movement of the wire from moving the first rotation axis, and recording the first resulting movement; moving the first translation axis, included as part of the first moveable manipulator, measuring a movement of the first gripper from moving the first translation axis, measuring a second resulting movement of the wire from moving the first translation axis, and recording the second resulting movement; moving the second rotation axis, included as part of the second moveable manipulator, measuring a movement of the second gripper from moving the second rotation axis, measuring a third resulting movement of the wire from moving the second rotation axis and recording the third resulting movement; moving the third rotation axis, included as part of the second moveable manipulator, measuring a movement of the second gripper from moving the third translation axis, measuring a sixth resulting movement of the wire from moving the third rotation axis, and recording the sixth resulting movement: developing a real model based on the movements of the axes of the first moveable manipulator and the second moveable manipulator and the corresponding recorded movements of the wire, wherein each of the axes of the first moveable manipulator and the second moveable manipulator are moved in different directions. 6. The method of claim 5 , wherein the resulting movements of the wire are measured by a vision system. 7. The method of claim 6 , wherein the vision system is configured to measure single bends in the wire as soon as they are made. 8. The method of claim 6 , further comprising iteratively bending and measuring bends in the wire until correct over-bending values are found. 9. The method of claim 5 , wherein the wire is made from an alloy.