Example implementations may relate to a robotic system configured to provide feedback. In particular, the robotic system may determine a model of an environment in which the robotic system is operating. Based on this model, the robotic system may then determine one or more of a state or intended operation of the robotic system. Then, based one or more of the state or the intended operation, the robotic system may select one of one or more of the following to represent one or more of the state or the intended operation: visual feedback, auditory feedback, and one or more movements. Based on the selection, the robotic system may then engage in one or more of the visual feedback, the auditory feedback, and the one or more movements.

The present disclosure relates a moving robot and a method for controlling thereof, and specifically, the moving robot and the method are configured to monitor a cleaning area by taking images while moving a plurality of areas based on a map of the cleaning area, and monitor in a plurality of areas or a dedicated specific area, and monitor overall areas by taking images while rotating at a monitoring location by dedicating the monitoring location in the area, and set a specific location in an area as a monitoring location, and cause taking of images to be performed at a specific angle by dedicating a monitoring direction in the monitoring location, and perform monitoring of a plurality of areas with minimal movement, and perform an effective monitoring because taking images in a blind spot may be performed by changing the monitoring location or adding a monitoring location based on information on an obstacle, and set a schedule to perform monitoring at a dedicated time, and detect invasion by recognizing the obstacle through analyzing of the images, and output an alert message or signal if the invasion is detected, and transmit a signal or message associated with the invasion detection, and thus a security function can be strengthened.

A robot system includes a cooking device to heat a cooking container and having an operation unit configured to select a temperature level; a robot configured to control the temperature level and a cooking time of the cooking device; a dust sensor disposed around the cooking device or on the robot to sense a concentration of foreign substances; a temperature sensor disposed around the cooking device or on the robot to sense a temperature of the cooking container or the cooking device; and a controller configured to control the robot in a safe mode such that at least one of the temperature level and the cooking time is varied according to a danger level determined by a concentration sensing value of the dust sensor and a temperature sensing value of the temperature sensor.

Example implementations may relate to a robotic system configured to provide feedback. In particular, the robotic system may determine a model of an environment in which the robotic system is operating. Based on this model, the robotic system may then determine one or more of a state or intended operation of the robotic system. Then, based one or more of the state or the intended operation, the robotic system may select one of one or more of the following to represent one or more of the state or the intended operation: visual feedback, auditory feedback, and one or more movements. Based on the selection, the robotic system may then engage in one or more of the visual feedback, the auditory feedback, and the one or more movements.

Systems and methods for detecting blind spots using a robotic apparatus are disclosed herein. According to at least one exemplary embodiment, a robot may utilize a plurality of virtual robots or representations to determine intersection points between extended measurements from the robot and virtual measurements from a respective one of the virtual robot or representation to determine blind spots. The robot may additionally consider locations of the blind spots while navigating a route to enhance safety, wherein the robot may perform an action to alert nearby humans upon navigating near a blind spot along the route.

A mobile robot configured for delivering consumable items to delivery recipients. The mobile robot comprises an item compartment with a top section, a separator, and a bottom section. The mobile robot also comprises a temperature control component. A method for delivering consumable items to delivery recipients using the mobile robot.

An apparatus for holding a cable for an electric vehicle charger includes a cable holding unit configured to restrict a charging cable extended and connected to a charging coupler, and to ascend or descend to predetermined positions, a housing unit mounted in a manner that is rotatable along a leftward-rightward direction, the cable holding unit being accommodated inside the housing unit, a driving unit configured to provide drive power for enabling the cable holding unit to ascend and descend and drive power for rotating the housing unit, and a control unit configured to control the driving unit in such a manner that the cabling holding unit and the housing unit are selectively driven when the charging coupler is removed from an electric vehicle charger or rests thereon.

Disclosed is a moving robot including: a travel unit configured to move a body; an image acquisition unit configured to acquire a surrounding image of the body; a sensor unit having one or more sensors configured to detect an obstacle while the body moves; a controller configured to: upon detection of an obstacle by the sensor unit, recognize an attribute of the obstacle based on an image acquired by the image acquisition unit, and control driving of the travel unit based on the attribute of the obstacle; and a sound output unit configured to: output preset sound when the recognized attribute of the obstacle indicates a movable obstacle. Accordingly, the moving robot improves stability, user convenience, driving efficiency, and cleaning efficiency.

Disclosed example robotic welding systems include: a robotic manipulator configured to manipulate a welding torch; and a robot control system, comprising: a processor; and a machine readable storage medium comprising machine readable instructions which, when executed by the processor, cause the processor to, during a robotic welding procedure involving the robotic manipulator: prior to initiating an arc as part of the robotic welding procedure, identify an arc warning event; in response to the arc warning event, output at least one of a visual notification or an audible notification proximate to the robotic manipulator; and control the robotic manipulator to perform the robotic welding procedure involving initiating the arc using the welding torch.

A system for the safe control of safety protections comprises at least one first control device (2) placed outside the safety perimeter (P) for sending commands to stop and enable the machine or plant (M) following the opening/closing of the accesses (A1, A2), a first safety switch (3) placed close to one or more of the accesses (A1, A2) for their locking and/or unlocking, one or more actuators having a transponder with identification code for interacting with the first control device and/or safety switch, at least one control unit operatively connected to the first control device and to the safety switch to receive the actuation commands and enable the operation of the machine or plant (M) between an operating condition of fully operation and a safety operating condition. Second means are also provided for enabling the exit from the safety perimeter (P) for one or more operators.