The present disclosure relates to a Web server (104, 60, 70) and a method therein of determining a trajectory for controlling of a robot device over a cloud interface. From a URI-encoded HTTP request (402) for the trajectory between a first pose and a second pose of the robot device, it is determined (S112, 408) the length of matching between cached trajectories and the trajectory requested. The longest length of matching is compared (S114, 410) to a minimal matching length (406), and if the longest length is longer than the minimal matching length, a HTTP response is sent (S122, 412) comprising the trajectory being determined. If the longest length is shorter than the minimal matching length, a HTTP request to calculate is sent (S116, 414). Currently available web service architecture can be reused, and easily up-scaled.

Provided are a method of controlling a mobile robot, apparatus for supporting the method, and delivery system using the mobile robot. The method, which is performed by a control apparatus, comprises acquiring a first control value for the mobile robot, which is input through a remote control apparatus, acquiring a second control value for the mobile robot, which is generated by an autonomous driving module, determining a weight for each control value based on a delay between the mobile robot and the remote control apparatus and generating a target control value of the mobile robot in combination of the first control value and the second control value based on the determined weights, wherein a first weight for the first control value and a second weight for the second control value are inversely proportional to each other.

A robotic device is disclosed that can have a plurality of non-dedicated, smart control devices. Each smart control device can provide smart functionality to control an operational function of the robotic device. In addition, a robotic system is disclosed that can include a robotic device having a local non-dedicated, smart control device providing smart functionality to control an operational function of the robotic device. The robotic device can also include a remote control device to communicate operational information with the local smart control device to facilitate user control of the robotic device.

A method for controlling an operation of an ultrasonic blade of an ultrasonic electromechanical system is disclosed. The method includes providing an ultrasonic electromechanical system comprising an ultrasonic transducer coupled to an ultrasonic blade via an ultrasonic waveguide; applying, by an energy source, a power level to the ultrasonic transducer; determining, by a control circuit coupled to a memory, a mechanical property of the ultrasonic electromechanical system; comparing, by the control circuit, the mechanical property with a reference mechanical property stored in the memory; and adjusting, by the control circuit, the power level applied to the ultrasonic transducer based on the comparison of the mechanical property with the reference mechanical property.

This invention relates to a system for teaching computer programming comprising a robot farm, a plurality of remote computing devices and a server. The robot farm comprises a plurality of pods, each housing a robot and having a video camera to capture live video of the robot in the pod. The computing devices are each associated with a robot and transmit control commands to the robot to cause the robot to carry out an action and in return receive live video footage of the robot. The server communicates with the robots, the video cameras and the plurality of remote computing devices to relay control commands from the computing devices to the robots and live video from the video cameras to the computing devices. The computing devices further comprise a user interface having panes, including a programming pane for receipt of control commands, and a video feed pane for displaying video feed of the robot.

A robotic system includes a robot having a picking arm to grasp an inventory item and a shuttle. The shuttle includes a platform adapted to receive the inventory item from the picking arm of the robot. The platform is moveable between a pick-up location located substantially adjacent to the robot and an end location spaced a distance apart from the pick-up location. The system improves efficiency as transportation of the item from the pick-up location to the end location is divided between the robot and the shuttle.

A graphical user interface for a remote controlled robot system that includes a robot view field that displays information provided by a robot and an observer view field that display observer information about one or more observers that can receive the robot information. The interface has various features that allow a master user to control the observation and participation of the observers.

In a control apparatus that controls communication of a telexistence system including a slave robot and an operating device, a state acquisition part repeatedly acquires status reports respectively from the operating device, the slave robot, and a plurality of virtual routers that connect the operating device and the slave robot while communication between the operating device and the slave robot is established. A path determination part determines a communication path for transmitting a control instruction for controlling the motion of the slave robot to the slave robot on the basis of the acquired status reports when the state acquisition part acquires the status reports. An instruction transmitting part transmits an instruction for forming the communication path determined by the path determination part to each of the plurality of virtual routers.

Provided are a method of controlling a mobile robot, apparatus for supporting the method, and delivery system using the mobile robot. The method, which is performed by a control apparatus, comprises acquiring a first control value for the mobile robot, which is input through a remote control apparatus, acquiring a second control value for the mobile robot, which is generated by an autonomous driving module, determining a weight for each control value based on a delay between the mobile robot and the remote control apparatus and generating a target control value of the mobile robot in combination of the first control value and the second control value based on the determined weights, wherein a first weight for the first control value and a second weight for the second control value are inversely proportional to each other.

A method of adjusting a staple parameter of a surgical stapling instrument is disclosed. The method includes determining, by a control circuit of the surgical stapling instrument, a first stroke length for a first staple driver of the surgical stapling instrument to drive a first row of staples of a circular stapling head assembly of the surgical stapling instrument; detecting, by the control circuit, a malformed staple in the first row of staples; adjusting, by the control circuit, the staple parameter, based on the detection of the malformed staple; and determining, by the control circuit, a second stroke length for a second staple driver of the surgical stapling instrument to drive a second row of staples of the circular stapling head assembly.