Devices, systems, and methods for social behavior of a telepresence robot are disclosed herein. A telepresence robot may include a drive system, a control system, an object detection system, and a social behaviors component. The drive system is configured to move the telepresence robot. The control system is configured to control the drive system to drive the telepresence robot around a work area. The object detection system is configured to detect a human in proximity to the telepresence robot. The social behaviors component is configured to provide instructions to the control system to cause the telepresence robot to operate according to a first set of rules when a presence of one or more humans is not detected and operate according to a second set of rules when the presence of one or more humans is detected.

A cleaning robot includes a main body, a traveling part provided at a lower portion of the main body to enable the main body to move along a floor surface, a suction part provided at the main body to suck foreign materials from the floor surface, a cover provided on an exterior of the main body, and a recessed part recessed at a predetermined position of the cover, wherein the cover includes a first cover positioned above the recessed part, and a second cover which is positioned below the recessed part and has a greater width than the first cover.

A robot includes a movable unit and a driving unit that drives the movable unit. The movable unit includes a predicted colliding section that is a structure forming an outer shape of the movable unit and may collide with a human body during movement of the movable unit. The predicted colliding section is formed to have a predetermined shape such that a pressure applied to a human body is lower than a predetermined safety standard value for pressure for the human body when the movable unit is driven at maximum thrust by the driving unit and collides with the human body.

An example method may include i) detecting a disturbance to a gait of a robot, where the gait includes a swing state and a step down state, the swing state including a target swing trajectory for a foot of the robot, and where the target swing trajectory includes a beginning and an end; and ii) based on the detected disturbance, causing the foot of the robot to enter the step down state before the foot reaches the end of the target swing trajectory.

A moving robot including: actuators at least including a motor for movement; a reading unit configured to read a tag installed in an environment, at least one of information on an allowable operation time of the actuators and information on an allowable operation amount of the actuators being described in the tag; and a controller configured to prohibit or limit execution of a predetermined task whose execution has already been accepted, the predetermined task being operated using at least one of the actuators, until the time when the reading unit reads the tag, and release the prohibition or the limitation and execute the task in such a way that an operation time and an operation amount do not exceed the allowable operation time and the allowable operation amount described in the tag after the reading unit has read the tag is provided.

An environment arrangement robot includes a map creation unit that divides the target space into a plurality of cell spaces and provides an evaluation value to each of the cell spaces, in which the evaluation value indicates a probability of whether or not there is an object in the corresponding cell space, and an environment change unit that changes, among the plurality of cell spaces, a specific cell space having the evaluation value within a range evaluated that the probability of whether or not there is an object in the specific cell is low in such a way that the probability that the object is present will become greater or change a surrounding cell space in such a way that the specific cell space will be excluded from the measurement by the distance sensor.

Generally, a system for use in a robotic surgical system may be used to determine an attachment state between a tool driver, sterile adapter, and surgical tool of the system. The system may include sensors used to generate attachment data corresponding to the attachment state. The attachment state may be used to control operation of the tool driver and surgical tool. In some variations, one or more of the attachment states may be visually output to an operator using one or more of the tool driver, sterile adapter, and surgical tool. In some variations, the tool driver and surgical tool may include electronic communication devices configured to be in close proximity when the surgical tool is attached to the sterile adapter and tool driver.

Generally, a sterile adapter for use in robotic surgery may include a frame configured to be interposed between a tool driver and a surgical tool, a plate assembly coupled to the frame, and at least one rotatable coupler supported by the plate assembly and configured to communicate torque from an output drive of the tool driver to an input drive of the surgical tool.

A cleaning robot includes a top cover, a bottom cover provided below the top cover, traveling parts provided in the bottom cover, a suction module provided in the bottom cover to suck in foreign materials on the ground, a recessed part firmed to be recessed inward between the top cover and the bottom cover, and a first sensor located in the recessed part.

Specialized robot motion planning hardware and methods of making and using same are provided. A robot-specific hardware can be designed using a tool that receives a robot description comprising a collision geometry of a robot, degrees of freedom for each joint of the robot, and joint limits of the robot; receives a scenario description; generates a probabilistic roadmap (PRM) using the robot description and the scenario description; and for each edge of PRM, produces a collision detection unit comprising a circuit indicating all parts of obstacles that collide with that edge. The hardware is implemented as parallel collision detection units that provide collision detection results used to remove edges from the PRM that is searched to find a path to a goal position.