A control system for controlling a surgical robot by a surgeon console remote from the surgical robot, the control system being configured to: receive one or more state signal associated with a plurality of instruments, each of the plurality of instruments being attachable to the surgical robot, the one or more state signal indicating a selectability of each of the plurality of instruments for control by the surgeon console, and a control mode of each of the plurality of instruments from a group of modes, the group of modes comprising a manipulation mode in which an instrument of the plurality of instruments is controllable by the surgeon console, and a selection mode in which an instrument of the plurality of instruments is selectable for control by the surgeon console; determine a graphical arrangement of icons for display in dependence on the received one or more state signal, where each icon represents a respective one of the plurality of instruments, and output a display signal to cause the graphical arrangement of icons to be displayed; receive a mode change signal indicating a change of mode to the selection mode; modify, in response to the received mode change signal, the graphical arrangement of icons to permit identification of selectable instruments of the plurality of instruments; receive a select signal from the surgeon console indicating a selection of one of the selectable instruments; modify, in response to the received select signal, the graphical arrangement of icons to permit identification of the selected instrument; and enable control of the selected instrument by the surgeon console.

A method and system for preventing a collision between mechanical arms (21), and a medical robot, belonging to the field of medical robot technology. The method includes: arranging (S10) discrete points (m, n) at a mechanical arm (21); acquiring (S40) an interaction force (F.sub.m,n) corresponding to each discrete point (m, n) according to a calculated relative distance (L) between the discrete points (m, n) respectively on different mechanical arms (21), to obtain (S50) a resultant force of the interaction forces (F.sub.m,n) each of which corresponds to each discrete point (m, n), and then obtaining a Cartesian force (F.sub.d) corresponding to each mechanical arm (21), and making (S60) an operator perceive the Cartesian force (F.sub.d) in real time, thereby effectively reducing the risk of interference and collision between the mechanical arms (21).

Devices, systems, and methods for providing commanded movement of an end effector of a manipulator while providing a desired movement of one or more joints of the manipulator. Methods include augmenting a Jacobian so that joint movements calculated from the Jacobian perform one or more auxiliary tasks and/or desired joint movements concurrent with commanded end effector movement, the one or more auxiliary tasks and/or desired joint movements extending into a null-space. The auxiliary tasks and desired joint movements include inhibiting movement of one or more joints, inhibiting collisions between adjacent manipulators or between a manipulator and a patient surface, commanded reconfiguration of one or more joints, or various other tasks or combinations thereof. Such joint movements may be provided using joint velocities calculated from the pseudo-inverse solution of the: augmented Jacobian. Various configurations for systems utilizing such methods are provided herein.

A system comprises a first robotic arm adapted to support and move a tool and a second robotic arm adapted to support and move a camera. The system also comprises an input device, a display, and a processor. The processor is configured to, in a first mode, command the first robotic arm to move the camera in response to a first input received from the input device to capture an image of the tool and present the image as a displayed image on the display. The processor is configured to, in a second mode, display a synthetic image of the first robotic arm in a boundary area around the captured image on the display, and in response to a second input, change a size of the boundary area relative a size of the displayed image.

Methods, apparatuses, and systems for edge computing for robotic telesurgery using artificial intelligence are disclosed. A robotic surgical system includes surgery equipment and can communicate via a cloud network. The system can include operation room (OR) equipment and a surgical computer. The surgical computer transfers data between a remote surgeon, the OR equipment, and the surgery equipment. The surgical computer receives, using the OR equipment and the surgery equipment, data related to a surgical procedure. The data is related to the surgical procedure and is computed using artificial intelligence (AI). The surgical computer determines a risk assessment based on data related to the surgery equipment. The surgical computer sends an indication of the determined risk assessment to the remote surgeon.

Robotic devices, systems, and methods for use in robotic surgery and other robotic applications, and/or medical instrument devices, systems, and methods includes both a reusable processor and a limited-use robotic tool or medical treatment probe. A memory the limited-use component includes machine readable code with data and/or programming instructions to be implemented by the processor. Programming of the processor can be updated by shipping of new data once downloaded by the processor from a component, subsequent components can take advantage of the updated processor without repeated downloading.

A computer-assisted medical system includes a display unit configured to provide images to an operator of the display unit, a headrest configured to receive a mechanical input provided by a head of the operator in mechanical contact with the headrest, a headrest sensor interfacing with the headrest and configured to provide sensor signals based on the mechanical input, and a controller. The controller includes a computer processor, and is configured to process the sensor signals to obtain a driving input, drive, by the driving input, a virtual mass to obtain a simulated virtual mass movement, and cause movement of the headrest, the movement of the headrest tracking the virtual mass movement.

A control system for controlling a surgical robot by a surgeon console remote from the surgical robot, the control system being configured to: receive one or more state signal associated with a plurality of instruments, each of the plurality of instruments being attachable to the surgical robot, the one or more state signal indicating a selectability of each of the plurality of instruments for control by the surgeon console, and a control mode of each of the plurality of instruments from a group of modes, the group of modes comprising a manipulation mode in which an instrument of the plurality of instruments is controllable by the surgeon console, and a selection mode in which an instrument of the plurality of instruments is selectable for control by the surgeon console; determine a graphical arrangement of icons for display in dependence on the received one or more state signal, where each icon represents a respective one of the plurality of instruments, and output a display signal to cause the graphical arrangement of icons to be displayed; receive a mode change signal.

Disclosed is a controller including a first control member, a second control member that extends from a portion of the first control member, and a controller processor that is operable to produce a rotational movement output signal in response to movement of the first control member, and a translational movement output signal in response to movement of the second control member relative to the first control member. The rotational movement output signal may be any of a pitch movement output signal, a yaw movement output signal, and a roll movement output signal, and the translational movement output signal may be any of an x-axis movement output signal, a y-axis movement output signal, and a z-axis movement output signal. In exemplary embodiments, the first control member may be gripped and moved using a single hand, and the second control member may be moved using one or more digits of the single hand, thus permitting highly intuitive, single-handed control of multiple degrees of freedom, to and including, all six degrees of rotational and translational freedom without any inadvertent cross-coupling inputs.

Systems and methods for adaptively and intraoperatively configuring an automated arm used during a medical procedure. The automated arm is configured to position and orient an end effector on the automated arm a desired distance and orientation from a target. The end effector may be an external video scope and the target may be a surgical port. The positions and orientations of the end effector and the target may be continuously updated. The position of the arm may be moved to new locations responsive to user commands. The automated arm may include a multi joint arm attached to a weighted frame. The weighted frame may include a tower and a supporting beam.