An apparatus, system and process for guiding a surgeon during a medical procedure to prevent surgical mistakes are described. The system may include a machine learning medical procedure server that generates one or more machine learning medical procedure models using, at least, medical procedure data captured during medical procedures performed at a plurality of different medical procedure systems. The system may also include a medical procedure system communicably coupled with the machine learning medical procedure server that receives a selected machine learning medical procedure model from the machine learning medical procedure server, and utilizes the selected machine learning medical procedure model during a corresponding medical procedure to control one or more operations of the medical procedure system.

A method for guiding in real time a robot arm for the processing of data of the surface of a body, includes generating a body model including a meshing of points; planning a treatment trajectory on the surface of the body model with a calculator; activating at least one transmission of a transmitter and/or acquisition of a sensor of an operator device, the operator device being arranged at the distal end of the robotised arm, the activation being carried out when the orientation of the axis of the sensor or the transmitter is merged with a predefined straight line passing through the target point, the target point being referenced on the generated body model.

Systems and methods for saturated robotic movement are provided. In one aspect, there is provided a robotic system, including a robotic arm configured to control movement of a medical instrument, and a processor configured to: receive a first user input from a user for moving the medical instrument with the robotic arm, determine that moving the robotic arm according to the first user input would cause a contact point of the robotic arm to contact or cross a collision boundary surrounding an object, and guide the movement of the robotic arm such that the contact point of the robotic arm continuously moves along the collision boundary based in part on the first user input, in response to the determination that moving the robotic arm according to the first user input would cause the contact point to contact or cross the collision boundary.

A hand controller for enabling a user to perform an activity and method for controlling a robotic arm is provided. The hand controller includes a bar with a grip and a plurality of motors to provide a force feedback to the user in response to the movement of the plurality of mechanical arms. The method involves receiving input corresponding to the manipulation of a bar and providing a force feedback in response to the movement of the plurality of mechanical arms.

A method of calibrating a torque sensor for a motor with a controller includes determining a gain of the torque sensor, zeroing a torque reading of the torque sensor, accelerating the motor at a known rate, and determining an inertia of the motor in response to accelerating the motor. Zeroing the torque reading occurs when the motor is in an unloaded and unactivated condition and accelerating the motor occurs when the motor is in an unloaded condition.

Robotic systems and methods employ a virtual simulation wherein a tool is represented as a virtual volume adapted to interact relative to a virtual boundary defined by a mesh of polygonal elements. A reactive force is computed in response to penetration of one of the polygonal elements by the virtual volume in the virtual simulation. The reactive force is computed as a function of a volume of a penetrating portion of the virtual volume that is penetrating a plane of the polygonal element. The reactive force is applied to the virtual volume in the virtual simulation for reducing penetration of the polygonal element by the virtual volume.

A robotic surgical system may include a table and at least one adjustable arm support that supports one or more robotic arms. The adjustable arm support may be capable of swinging horizontally in a direction of the table. A plate extension may extend outward from the adjustable arm support. An extender bar may be coupled to one or more of the robotic arms and a cannula. A height differential may be provided between a first robotic arm and a second robotic arm that is supported on the adjustable arm support.

A hand controller for enabling a user to perform an activity and method for controlling a robotic arm is provided. The hand controller includes a bar with a grip and a plurality of motors to provide a force feedback to the user in response to the movement of the plurality of mechanical arms. The method involves receiving input corresponding to the manipulation of a bar and providing a force feedback in response to the movement of the plurality of mechanical arms.

Surgical systems and methods for generating a tool path. A manipulator is configured to support and move a surgical instrument. Controller(s) obtain data that defines a volume of tissue to be removed from a surgical site. The controller(s) operate the manipulator to move the surgical instrument to remove first portions of the volume and acquire data defining the first portions removed from the volume. The controller(s) identify, based on the volume and the acquired data, additional portions of the volume of tissue that require removal. The controller(s) generate a tool path that passes through the additional portions and operate the manipulator to move the surgical instrument along the tool path to remove the additional portions.

Disclosed herein is a robot arm control system of an automated medication dispensing apparatus, which includes a robot arm; a storage configured to store a mounting position of each of a plurality of medication cassettes, an operation control value of the robot arm for moving to the mounting position, and a reference position at which the marker is attached to each medication cassette in a medication cassette storage unit where a plurality of racks in which the plurality of medication cassettes with markers attached thereto are mounted are arranged; a camera configured to capture the marker attached to the medication cassette; and a control unit configured to control the robot arm to move to a mounting position of any one among the medication cassettes to unload the medication cassette.