A surgical robotic system offers automation templates, such as surgical task templates, for collaborative control of the robot arms operating in an automated manner. This automated operation through integration of template selection and programming may reduce fatigue while maintaining accuracy and dexterity. For more routine parts of the surgery, the surgeon may select a template and use the template interface to set various parameters for a given surgery, such as the force to be applied, order of tasks, trajectory of movement, stop points, and/or distance of any given movement in automatic operation for surgeon verification. By automating parts of the surgery, the surgeon may use direct control for more sensitive aspects of the surgery while having a respite or assistance for more routine aspects of the surgery.

In one embodiment, the present disclosure includes a cloud computer system for controlling a plurality of remote devices comprising a cloud server including a cloud based operating system comprising a data model stored in a computer memory. The data model includes commands that may be performed by a plurality of remote devices in a remote system and, for each remote device, one or more operations for triggering processes executed by the remote device. The cloud based operating system generates a set of instructions from the plurality of commands and corresponding operations to control a portion of the remote devices to perform a task.

In one embodiment, a cloud computer system is disclosed for controlling a plurality of remote devices comprising a cloud server including a cloud based operating system comprising a data model stored in a computer memory. The data model includes commands performed by a plurality of remote devices in a remote system and, for each remote device, one or more operations for triggering processes executed by the remote device. The cloud based operating system generates a set of instructions from the plurality of commands and corresponding operations to control a portion of the remote devices to perform a task.

A mobile robot is configured for operation in a commercial or industrial setting, such as an office building or retail store. The mobile robot can have a motorized base and a robot body on the motorized base, the robot body including a rotatable ring that rotates horizontally around the robot body. A mechanical arm that can contract and extend relative to the robot body is coupled to the rotatable ring and performs a plurality of actions. A controller of the mobile robot provides instructions to the rotatable ring and the mechanical arm and can cause the mechanical arm to open a door, take an elevator to move to a different floor, and test whether a door is locked properly.

Provided is an agent robot control system comprising an acquisition unit which acquires a purchasing master list which shows a user's purchase merchandise candidates, and a control unit which generates a purchasing execution list for recommending, from the purchasing master list, purchases for select merchandise to be performed at real storefronts and for recommending purchases for other merchandise to be performed at online storefronts.

A control device includes at least two processors comprising at least a first processor and a second processor. The control device controls at least one autonomous motion mechanism on the basis of a recognition result received from a recognition device. A storage device of the control device stores upper-level software, middle-level software, and lower-level software. The upper-level software derives a feature amount representing a feature of the recognition result. The middle-level software generates a motion plan of the autonomous motion mechanism on the basis of the feature amount. The lower-level software outputs a command value for controlling the autonomous motion mechanism on the basis of the motion plan. The first processor executes at least the upper-level software, the second processor executes at least the lower-level software, and at least one processor included in the control device executes the middle-level software.

A control method for a robot system is provided. The robot system includes a plurality of motion arms, and the plurality of motion arms include a first motion arm and a second motion arm. The control method includes: determining a motion mode of ends of the first motion arm and the second motion arm of the robot system, where the motion mode includes synchronous motion of the ends of the first motion arm and the second motion arm; determining motion paths of the first motion arm and the second motion arm based on the motion mode and a relative end pose relationship between the first motion arm and the second motion arm; and controlling, based on the corresponding motion paths, the first motion arm and the second motion arm to move.

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.

Whether or not workpieces are present in a workpiece storage area is determined based on an image acquired by image capturing. When the workpieces are determined to be present, whether or not a crossing part is present in the workpiece storage area is determined based on the image, the crossing part being a part where soft body portions of a plurality of workpieces cross each other in an overlapping manner. When the crossing part is determined to be present, an uppermost soft body portion placed at an uppermost position among the soft body portions crossing each other is determined based on the image. A workpiece including the uppermost soft body portion thus determined is determined as an uppermost workpiece placed at an uppermost position.

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.