Described herein is a framework for efficient task-agnostic, user-independent adaptive teleoperation of mobile robots and remotely operated vehicles (ROV), including ground vehicles (including legged systems), aircraft, watercraft and spacecraft. The efficiency of a human operator is improved by minimizing the entropy of the control inputs, thereby minimizing operator energy and achieving higher performance in the form of smoother trajectories by concurrently estimating the user intent online and adaptively updating the action set available to the human operator.

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.

The invention relates to a system and method for changing liners of a mill, the configuration of which allows the automated robotic manipulation of liners of mills for ore grinding in comminution processes. The configuration and operation of the system allows the task of manipulation to be improved, having a greater degree of freedom and/or flexibility in its movements, thereby providing a greater degree of certainty and efficiency to the method and thus optimising the time that the mill is halted for maintenance, and also preventing the risks to which maintenance staff may be exposed. The system comprises at least one support structure, at least one system for supplying and moving liners, at least one robotic manipulator system for manipulating the liners, at least one liner manipulation tool, at least one artificial vision system, and at least one control system.

A robot includes a filming unit that films a periphery, and a movement control unit that controls a distance from a filmed target object in accordance with a size of the target object. The robot may further include an operation control unit that controls an operation of a head portion, and a recognizing unit that recognizes a face of the filmed target object. The operation control unit may control the operation of the head portion so that a line of sight of the head portion reaches an angle of looking up directed at the face of the target object. The movement control unit may control the distance from the target object in accordance with a height of the target object.

An object recognizer recognizes a position and an attitude of a target object based on data measured by a sensor. A safe distance calculator calculates a distance from the target object to a certain object which is other than an object manipulation apparatus and the target object. A manipulation controller controls the pickup device based on the position and the attitude of the target object, and based on the distance from the target object to the certain object. When there are a plurality of target objects to be selected by the object manipulation apparatus, the manipulation controller selects one of the target objects having distances to the certain object longer than a predetermined threshold, and manipulates the selected target object using the pickup device.

[Problem] To provide an agent robot control system, agent robot system, agent robot control method, and recording medium, which are capable of assisting in optimal shopping in real storefronts and online storefronts. [Solution] 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 robot control device includes: a measuring unit to measure a robot control state indicative of a position and a posture of the robot; a work area setting unit to store, for each of work processes, a work area that is defined by work movement of the worker between a start and an end of each of the work processes and includes a space a body of the worker occupies and to set the work area corresponding to the work process currently carried out by the worker based on a signal specifying the work process currently carried out by the worker; and a robot command generator to generate a motion command for the robot based on the work area and the robot control state. The generator varies the command for the robot based on whether the robot is present in the work area.

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 robot operation evaluation device includes: an operational state calculator for calculating an operational state of an evaluation region that is a movable region of a robot, based on an operational state of the robot; a shape-feature quantity calculator for calculating a shape-feature quantity depending on an operation direction of the evaluation region corresponding to the operational state calculated; and an evaluation value calculator for calculating an evaluation value representing a risk degree of the operational state of the evaluation region with respect to the operation direction, based on the shape-feature quantity.

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.