In a robotic surgical system, an operation unit includes a drive to assist an operation of an operator. A controller is configured or programmed to control the drive to exert a braking force when the operation on the operation unit is decelerated and/or accelerated.

A surgical robotic system includes a plurality of magneto sensors for measuring a torque, axial force, angle, position, or speed of various driven members in the surgical robotic system.

A surgical robotic platform operates within a constrained space of an imaging scanner in which a patient resides. The platform includes a gross positioning stage configured to be located outside of the constrained space An end-effector having a rotatable shaft is extendable from the gross positioning stage and into the constrained space of the imaging scanner. The shaft has a proximal end operatively coupled to the positioning stage outside of the constrained space and a distal end configured to be located in the constrained space. The distal end has a medical instrument gripper for holding a medical instrument used in a percutaneous procedure. The end-effector further includes a joint arrangement operatively coupling the shaft to the medical gripper for providing motion to the medical instrument gripper for enabling position and/or orientation control of the medical instrument. A drive module controls the joint arrangement.

Example embodiments relate to robotic arm assemblies. Embodiments of the robotic arm assembly include a shoulder segment and upper arm segment having a motor drive portion. Embodiments also include a shoulder coupling joint assembly connecting the upper arm segment to the shoulder segment. Shoulder coupling joint assembly includes a distal shoulder joint subassembly connected to the upper arm segment. The distal shoulder joint subassembly includes a distal shoulder joint forming a first axis. The distal shoulder joint subassembly includes a shoulder planetary gear assembly. Embodiments include an elbow coupling joint assembly connecting the upper arm segment to the forearm segment. The elbow coupling joint assembly includes a proximal elbow joint subassembly connected to the upper arm segment. The proximal elbow joint subassembly includes a proximal elbow joint forming a second axis. The proximal elbow joint subassembly includes an elbow planetary gear assembly.

A surgical apparatus system for minimally invasive surgery (MIS) which includes a wrist assembly. The wrist assembly includes a first jaw, a first actuation hub, and a cable redirecting hub operably coupled to the first actuation hub, a second jaw, a second actuation hub, a housing for the first and second jaws, a first cable, a second cable, a third cable, rotational position sensors, and a control system. The first and second jaws of the wrist assembly are movably opposed, and the cables are configured such that applying tensions upon them cables produces rotation about a jaw axis. The wrist assembly may further include a hinge-rotary assembly to configured to provide rotation about a pitch axis and/or a roll axis. The wrist assembly may further include a fourth cable configured such that applying tensions upon the fourth cable and the opposing cable produces rotation about a pitch axis.

A surgical instrument includes a shaft, an end effector, and an articulation mechanism. The end effector is movable between a first position where the end effector is aligned with a longitudinal axis of the shaft, and a second position where the end effector is disposed at an angled relative to the longitudinal axis. The articulation mechanism includes a proximal gear disposed in mechanical cooperation with the shaft, a distal gear disposed in mechanical cooperation with the end effector, a first lateral gear disposed in contact with the proximal gear and the distal gear, and a second lateral gear disposed in contact with the proximal gear and the distal gear.

In a surgical robot, a robot controller controls an articulated robot so that an arm base rotationally moves in an arc shape around a predetermined position set at a position away from the arm base.

An operating arm (100) includes a driving cartridge (1), a link (2), an end instrument (3), and a first group driving wire (4) and a second group driving wire (5) penetrating the link (2). The end instrument (3) includes a connecting assembly (6) connected to the link (2) and an end effector (7) connected to the connecting assembly (6). The driving cartridge (1) includes a base (10) connected to the link (2), a first rotatable shaft (111) arranged on the base (10), and a second rotatable shaft (112) arranged on and rotating coaxially with the first rotatable shaft (111). The first group driving wire (4) starts from the first rotatable shaft (111) and terminates at a first position of the connecting assembly (6). The second group driving wire (5) starts from the second rotatable shaft (112) and terminates at a second position of the connecting assembly (6).

A robotic surgical system is provided with a central drive unit that supports and operates one or more robotic tools and a robotic arm and boom assembly that movably supports the control unit assembly in space. The robotic arm and boom assembly selectively allows movement of the control unit assembly along a plane, as well as in pitch and yaw, upon actuation of one or more actuators of the robotic arm and boom assembly to allow movement of the central drive unit.

Co-manipulation robotic systems are described herein that may be used for assisting with laparoscopic surgical procedures. The co-manipulation robotic systems allow a surgeon to use commercially-available surgical tools while providing benefits associated with surgical robotics. Advantageously, the surgical tools may be seamlessly coupled to the robot arms using a disposable coupler while the reusable portions of the robot arm remain in a sterile drape. Further, the co-manipulation robotic system may operate in multiple modes to enhance usability and safety, while allowing the surgeon to position the instrument directly with the instrument handle and further maintain the desired position of the instrument using the robot arm.