Abstract: A robotic surgical system (10) includes a multiple degree of freedom manipulator arm (14) having a surgical tool (22). The arm is coupled to a controller (24) for controllably positioning the surgical tool within a three dimensional coordinate system. The system further includes a safety monitoring processor (38) for determining the position of the surgical tool in the three dimensional coordinate system relative to a volumetric model. The volumetric model may be represented as a constructive solid geometry (CSG) tree data structure. The system further includes an optical tracking camera system (28,32) disposed for imaging a region of space that includes at least a portion of the manipulator arm. An output of the camera system is coupled to the processor (38) that processes the volumetric model for determining if the surgical tool is positioned outside of the volumetric model.

Abstract: The system and method includes a manipulator for manipulating a surgical instrument relative to a patient's body and, a position sensor for sensing the position of the surgical instrument relative to the patient's body. The manipulator can be manually or computer actuated and can have brakes to limit movement. In a preferred embodiment, orthogonal only motion between members of the manipulator is provided. The position sensor includes beacons connected to the patient and manipulator or surgical instrument and, a three dimensional beacon sensor adapted to sense the location and position of the beacons. Redundant joint sensors on the manipulator may also be provided. The system and method uses a computer to actively interact with the surgeon and can use various different input and output devices and modes.

Abstract: An apparatus used to assist a surgeon in surgery is divided into two parts, proximal and distal. The apparatus has a number of rigid links which rotate about pivots to position and re-position an instrument, like a surgical instrument, at a work point proximal to a patient but remote from the apparatus. The links cooperate in a way to move the manipulator about a center-of-motion with orthogonally decoupled degrees of freedom resolved at the work point.The proximal part of the apparatus is adjustably fixed to a stationary object, like an operating table, while the distal part of the apparatus holds the instrument. Certain links which can be adjusted in length, move the distal part with respect to the proximal part of the apparatus. In this manner, the work point of the manipulator and the working radius of the apparatus are changed without moving the proximal part. Actuators, manual or remotely (computer) controlled, both rotate the links about their pivots and adjust the length of the adjustable links.

Abstract: The present method and apparatus determines an interference-free trajectory for fitting a moving solid body into a cavity, particularly where the body has a complex shape and tightly fits into the cavity. The method begins by describing the body surface with a finite set of body surface elements and the cavity surface with a finite set of cavity surface elements. Then a set of surface element pairs is determined. Each set comprises a body surface element and a corresponding cavity surface element. A neighborhood is a volume that contains the pair of surface elements but no other surface element pairs or parts of surface elements. Body motion constraints are developed for each pair. The constraints do not allow the body motion to cause the surface elements in the pair to interpenetrate or to leave their respective neighborhood. An incremental movement of the body, along a preferred direction, is then determined subject to the constraints.

Abstract: A robotic surgical system includes a multiple degree of freedom manipulator arm having a surgical tool. The arm is coupled to a controller for controllably positioning the surgical tool within a three dimensional coordinate system. The system further includes a safety monitoring processor for determining the position of the surgical tool in the three dimensional coordinate system relative to a volumetric model. The volumetric model may be represented as a constructive solid geometry (CSG) tree data structure. The system further includes an optical tracking camera system disposed for imaging a region of space that includes at least a portion of the manipulator arm. An output of the camera system is coupled to the processor that processes the volumetric model for determining if the surgical tool is positioned outside of the volumetric model. The system further includes a strain gage for detecting slippage in three dimensions between an immobilized tissue, such as bone, and a reference point.

Abstract: The system and method includes a manipulator for manipulating a surgical instrument relative to a patient's body and, a position sensor for sensing the position of the surgical instrument relative to the patient's body. The manipulator can be manually or computer actuated and can have brakes to limit movement. In a preferred embodiment, orthogonal only motion between members of the manipulator is provided. The position sensor includes beacons connected to the patient and manipulator or surgical instrument and, a three dimensional beacon sensor adapted to sense the location and position of the beacons. Redundant joint sensors on the manipulator may also be provided. The system and method uses a computer to actively interact with the surgeon and can use various different input and output devices and modes.

Abstract: A robotic surgical system (10) includes a multiple degree of freedom manipulator arm (14) having a surgical tool (22). The arm is coupled to a controller (24) for controllably positioning the surgical tool within a three dimensional coordinate system. The system further includes a safety monitoring processor (38) for determining the position of the surgical tool in the three dimensional coordinate system relative to a volumetric model. The volumetric model may be represented as a constructive solid geometry (CSG) tree data structure. The system further includes an optical tracking camera system (28, 32) disposed for imaging a region of space that includes at least a portion of the manipulator arm. An output of the camera system is coupled to the processor (38) that processes the volumetric model for determining if the surgical tool is positioned outside of the volumetric model.

Abstract: This precision probe uses optical feedback in the X and Y dimensions to locate a microprobe in the airspace over a test pad, and uses pressure feedback in the Z dimension to control Z approach and penetration. The precision probe inspects a target by coarse positioning a guided microprobe to make contact at a selected probe pad. Guidance is optical, by light reflected, from a target by a dual mirror focusing system of concave mirror and flat mirror, to a transducer. Up and down Z positioning of the microprobe is carried out by a shaft positioned by an air diaphragm which is driven to the target by applied air pressure delivered via an air tube, providing the desired penetration of microprobe to microtarget. The probe is retracted by atmospheric pressure.

Abstract: A drillhole centerline determining interposer having a central cavity enables a robot to probe the interposer to learn the location and orientation of the desired drillhole. The interposer is a mushroom shaped device with a planar head and a stem dimensioned to fit snugly in the hole to be drilled. The interposer, in addition to the planar head from which the perpendicular can be calculated through multiple probes, has a central pocket concentric to the interposer stem.The method of using the drillhole centerline determining interposer is to place a number of such interposers manually in position in holes in a master part located in the work envelope of the robot. The robot operator prepositions the probe at an initial position facing the cavity of the interposer for a drillhole locating sequence for the related drillhole. In sequence, the robot moves the probe from the initial position sufficient to clear the edge of the cavity and by multiple probes determines the plane of the interposer surface platform.