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.

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.

A joint actuator includes a motor, a first gear part configured to change a direction of a rotational driving force applied by the motor and increase the applied rotational driving force, a spring member, a degree of a torsional deflection of Which is determined by a rotational. driving force supplied by the first gear part, and a second gear part configured to receive a rotational driving force according to the degree of the torsional deflection from the spring member. The first gear part includes a worm gear and a worm wheel gear configured to selectively engage with the worm gear. A joint structure includes the joint actuator mounted on a housing thereof and a joint unit coupled to the housing to be rotatably driven by the joint actuator.

A joint actuator includes a motor, a first gear part configured to change a direction of a rotational driving force applied by the motor and increase the applied rotational driving force, a spring member, a degree of a torsional deflection of Which is determined by a rotational. driving force supplied by the first gear part, and a second gear part configured to receive a rotational driving force according to the degree of the torsional deflection from the spring member. The first gear part includes a worm gear and a worm wheel gear configured to selectively engage with the worm gear. A joint structure includes the joint actuator mounted on a housing thereof and a joint unit coupled to the housing to be rotatably driven by the joint actuator.

A mobile character control system that includes a platform, a character assembly, a control system, and a transportation assembly. The platform is configured to support an operator. The character assembly is engaged with the platform and includes actuatable features configured to simulate movement of a creature. The control system is configured to control activation of the actuatable features of the character assembly in response to signals received from control features controlled by the operator. The transportation assembly is configured to direct movement of the platform, and the transportation assembly is configured to support the character assembly.

A mobile character control system that includes a platform, a character assembly, a control system, and a transportation assembly. The platform is configured to support an operator. The character assembly is engaged with the platform and includes actuatable features configured to simulate movement of a creature. The control system is configured to control activation of the actuatable features of the character assembly in response to signals received from control features controlled by the operator. The transportation assembly is configured to direct movement of the platform, and the transportation assembly is configured to support the character assembly.