A method for engaging and disengaging a surgical instrument of a surgical robotic system including receiving a sequence of user inputs from one or more user interface devices of the surgical robotic system; determining, by one or more processors communicatively coupled to the user interface devices and the surgical instrument, whether the sequence of user inputs indicates an intentional engagement or disengagement of a teleoperation mode in which the surgical instrument is controlled by user inputs received from the user interface devices; in response to determining of engagement, transition the surgical robotic system into the teleoperation mode; and in response to determining of disengagement, transition the surgical robotic system out of the teleoperation mode such that the user interface devices are prevented from controlling the surgical instrument.

A medical handling device comprises an instrument holder for holding an observation instrument that is equipped with an image capturing unit for capturing an image section. The handling device further comprises a robotic handling unit that supports the instrument holder and a control device that comprises a handling control unit for controlling the robotic handling unit and an instrument control unit for controlling the observation instrument. An input device is coupled to the control device for selecting an image section to be reproduced. The control device is adapted to control the robotic handling unit in response to user inputs at the input device to change the captured image section. The control device is adapted to convert operating commands at the input device into movement instructions, depending on a present orientation of the image capturing unit.

Provided is a master console for a surgical robot. The master console includes: a base unit including a first base and a second base, the first and second bases being provided parallel to each other; and a foot pedal unit between the first base and the second base, wherein the foot pedal unit includes at least one foot pedal switch capable of being manipulated by a foot of an operator, a foot panel configured to support the at least one foot pedal switch, and a footrest extending outward from the foot panel.

Provided is a master console for a surgical robot. The master console includes: a base unit including a first base and a second base, the first and second bases being provided parallel to each other; and a foot pedal unit between the first base and the second base, wherein the foot pedal unit includes at least one foot pedal switch capable of being manipulated by a foot of an operator, a foot panel configured to support the at least one foot pedal switch, and a footrest extending outward from the foot panel.

A foot pedal assembly for controlling a robotic surgical system includes a foot pedal assembly base including an axle, a foot pedal slidably and pivotally coupled to the axle, and a sensor arrangement configured to detect an axial position of the foot pedal along the axle and a pivoted position of the foot pedal around the axle. Different combinations of different detected axial positions and detected pivoted positions are correlateable to different functions of the robotic surgical system.

A foot pedal assembly for controlling a robotic surgical system includes a foot pedal assembly base including an axle, a foot pedal slidably and pivotally coupled to the axle, and a sensor arrangement configured to detect an axial position of the foot pedal along the axle and a pivoted position of the foot pedal around the axle. Different combinations of different detected axial positions and detected pivoted positions are correlateable to different functions of the robotic surgical system.

An integrated control system for a surgical robot based on embedded computers is provided. The system comprises a main control terminal and a controlled terminal. The main control terminal and the controlled terminal perform the exchange. A remote control device and pedals are connected with the host computer. The host computer performs the exchange of the control signals and the status signals with the controlled terminal through a control cabinet. When the pedal is depressed, the remote control device controls motions of a certain tool with which a mapping relationship is established. When the pedal is released, the corresponding motion control is cut off. The host computer is configured to perform the exchange of the control signals and the status signals with the controlled terminal through a control cabinet.

An integrated control system for a surgical robot based on embedded computers is provided. The system comprises a main control terminal and a controlled terminal. The main control terminal and the controlled terminal perform the exchange. A remote control device and pedals are connected with the host computer. The host computer performs the exchange of the control signals and the status signals with the controlled terminal through a control cabinet. When the pedal is depressed, the remote control device controls motions of a certain tool with which a mapping relationship is established. When the pedal is released, the corresponding motion control is cut off. The host computer is configured to perform the exchange of the control signals and the status signals with the controlled terminal through a control cabinet.

Methods and apparatuses for positioning a camera of a surgical robotic system to capture images inside a body cavity of a patient during a medical procedure are disclosed. In some embodiments, the method involves receiving location information at a controller of a surgical robotic system performing the medical procedure, the location information defining a location of at least one tool with respect to a body cavity frame of reference, and in response to receiving an align command signal at the controller, causing the controller to produce positioning signals operable to cause the camera to be positioned within the body cavity frame of reference to capture images of the at least one tool for display to an operator of the surgical robotic system.

Methods and apparatuses for positioning a camera of a surgical robotic system to capture images inside a body cavity of a patient during a medical procedure are disclosed. In some embodiments, the method involves receiving location information at a controller of a surgical robotic system performing the medical procedure, the location information defining a location of at least one tool with respect to a body cavity frame of reference, and in response to receiving an align command signal at the controller, causing the controller to produce positioning signals operable to cause the camera to be positioned within the body cavity frame of reference to capture images of the at least one tool for display to an operator of the surgical robotic system.