A force transmission transmits forces received by three levers to an input gimbal plate having three support points. The input gimbal play may in turn transmit the force to a wrist assembly coupled to a surgical tool. The three axes of rotation for the three levers are parallel. Two of the levers may have half-cylinder surfaces at an end of the lever to receive a support point of the input gimbal plate. Two of the levers may be supported with one degree of rotational freedom orthogonal to the axis of rotation of the fulcrum. A spring may draw the second and third levers toward one another. Two levers may have stops that bear against the support points. The force transmission may include a parallelogram linkage that includes a rocker link pivotally coupled to the first lever and having a flat surface that supports the first gimbal support point.

Disclosed herein are system, method, and computer program product embodiments a 6 degree-of-freedom (6DoF) correction trajectory in order to compensate movement of a treatment target in a patient supported by a patient support end-effector. An embodiment operates by receiving a starting end-effector position, a starting clinical target position, and a target destination position. The target destination position corresponds to a position in space receiving targeted treatment from a treatment delivery device. The embodiment determines a destination end-effector position in 6DoF associated with the end-effector that would cause the target to be positioned on the target destination position. A trajectory is calculated between the starting end-effector position and the destination end-effector position. The embodiment transmits, to a mechanical device controlling movement of the end-effector, one or more signals causing the end-effector to move from the starting end-effector position to the destination end-effector position along the determined trajectory.

A fuel vaporizer including fuel injectors is described herein. The vaporizer includes a housing having a plurality of baffles defining a plurality of chambers, with each of the plurality of baffles defining an aperture between adjacent chamber, and the apertures define a flow path from the air inlet, through the plurality of chambers, and to the vapor outlet. A conduit extends through the baffles and chambers, and the conduit is adapted to accept a flow exhaust gas and transfer thermal energy from the exhaust gas to an airflow along the flow path A fuel injector is positioned in the housing to inject fuel into the flow path in the first chamber, the thermal energy from the conduit vaporizing the fuel injected into the airflow and producing the flow of vaporized fuel. The fuel vaporizer may include a heat exchanger pre-heating the airflow and electric heating elements supplementing the conduit heating.

Provided is a method for forming an implant with an autonomous manufacturing device. The method includes accessing a first computer-readable reconstruction of a being's anatomy; accessing a second computer-readable reconstruction of an implant; accessing a third computer-readable reconstruction comprising the first computer-readable reconstruction superimposed with the second computer readable reconstruction; generating at least one computer-readable trace from a point cloud; and forming an implant with an autonomous manufacturing device, wherein the autonomous manufacturing device forms the implant into a shape defined by at least one dimension of the computer-readable trace.

Systems and methods for performing concomitant medical procedures are disclosed. In one aspect, the method involves controlling a first robotic arm to insert a first medical instrument through a first opening of a patient and controlling a second robotic arm to insert a second medical instrument through a second opening of the patient. The first robotic arm and the second robotic arm are part of a first platform and the first opening and the second opening are positioned at two different anatomical regions of the patient.

A method includes obtaining an implant plan, defining a range of motion for a surgical tool based on the implant plan, adjusting, by an actuator and based on the range of motion, a passive joint coupled between the actuator and the surgical tool, and allowing manual movement of the surgical tool through the range of motion via rotation at the passive joint.

A medical device has been disclosed. The medical device includes a parallel manipulator. The parallel manipulator having an end platform coupled to a surgical tool and a base platform coupled to machine module. The machine module is coupled to the surgical tool through a transmission shaft disposed between the end platform and the base platform.

A method and apparatus for steering of a flexible needle into tissue using a steering robotic platform for manipulation of the needle shaft, and by use of a semi-active arm for locating and orienting of the steering robot on the patient's body. As opposed to other steering methods, the robot does not hold the base of the needle, which is its proximal region, but rather grips the shaft of the needle by means of a manipulatable needle gripping device, near its distal end. The needle gripper attached to the robotic platform may be equipped with a traction assembly to provide motion to the needle in its longitudinal direction, such that it co-ordinates the entry of the needle with the desired entry angle. The gripping of the needle at its distal end, close to its insertion point, provides the needle manipulator with a low profile, with concomitant advantages.

A robotic device mounted on the head of a patient has a pivoted arm that extends down to support an article, such as a part of the jaw of the patient in orthognathic surgery. The pivoted arm is on a support plate that is in turn supported by a hexapod assembly that connects with a U-shaped bracket secured to the patient's head. The hexapod is computer controlled to adjust the position of the support plate relative to the head of the patient to precisely locate the supported article on the patient, such as where a separated portion of the patient's jaw is positioned for reattachment in orthognathic surgery.

A control method for a surgical robotic arm, a computer device and a surgical robotic arm are provided. The control method includes calculating a telecentric fixed point on an executing rod according to a target point and controlling a preoperative positioning assembly to advance a first movable platform of a telecentric manipulating assembly along a first coordinate axis of a movable coordinate system; calculating a first origin coordinate of an origin of the first movable platform in a stationary coordinate system according to the coordinate of the telecentric fixed point and the trajectory coordinate of an end point; calculating the length of a first telescopic element of the telecentric manipulating assembly according to the coordinates of a hinge point of the telecentric manipulating assembly in the stationary coordinate system; and controlling the first movable platform to move to a designated pose.