A piled grain surface management robot comprises an auger-based drive system, a memory, and a processor coupled with the memory. The processor is configured to control movement of the robot via the auger-based drive system. The processor is also configured to direct a traversal of a surface of piled grain in a bulk store, wherein a crust layer of the surface is broken up by auger rotation of the auger-based drive system during the traversal.

Measures for use in operating a robot having one or more sensors. A representation of an environment of the robot is generated by operating the one or more sensors to sense a set of parameters representative of the environment of the robot. A list of objects in the environment and associated identifiers for each object in the list is generated. Control data is received from the electronic user device. The control data includes an identifier for an object in the generated list that a user of the electronic user device wishes to locate within the environment. In response to receipt of the control data, the robot and the one or more sensors are operated to search the environment to determine a location of the identified object in the environment.

A remote operated underwater vehicle, ROV, is provided, where the ROV includes at least one extendible pair of tubulars supported on the ROV, the one tubular of the pair being movable longitudinally relative to the other tubular of the pair, for extending a combined reach of the tubulars; and at least one pump connected to the tubulars, the pump being operable for pumping or suctioning fluid through the pair.

A module type home robot is provided. The module type home robot includes a device module coupling unit coupled to a device module, an input unit receiving a user input, an output unit outputting voice and images, a sensing unit sensing a user, and a control unit sensing a trigger signal, activating the device module or the output unit according to the sensed trigger signal, and controlling the module type home robot to perform an operation mapped to the sensed trigger signal. The trigger signal is a user proximity signal, a user voice signal, a user movement signal, a specific time sensing signal or an environment change sensing signal.

A mobile robotic arm configured to provide on-demand assistance is disclosed. In an example, a robotic system includes a platform, at least two wheels connected to the platform and driven by respective motors, a robotic arm having a base that is connected to the platform, an end-effector connected to the robotic arm at an end opposite the base, and a processor communicatively coupled to the respective motors, the robotic arm, and the end-effector. The processor is configured to receive a command or determine that an item has fallen on a floor, locate the item on the floor, determine a distance and a heading to the item, cause the respective motors to move the platform to the item within range of the robotic arm, cause the robotic arm to grasp the item with the end-effector, and cause the robotic arm to provide the item to a user.

A multiplex device including a multiplex connecting section connected to a movable side multiplex device, the multiplex connecting section being configured to transmit a position signal outputted from a position signal output section connected to the movable side multiplex device by multiplexing communication with the movable side multiplex device; an amplifier connecting section connected to a position signal output section amplifier, the amplifier being configured to transmit the position signal to the position signal output section amplifier; a measuring device connecting section connected to a position signal measuring device; and a switching section configured to switch from a connection between the multiplex connecting section and the position signal output section amplifier, and a connection between the multiplex connecting section and the position signal measuring device in accordance with detection of a connection between the measuring device connecting section and the position signal measuring device.

A moving robot includes a main body; a moving module configured to move the main body; a communication device including an antenna module arranged in a highest portion within the main body and performing wireless communication with an external device; and at least one processor configured to control the moving module based on a signal received from the external device through the communication device so that the main body moves toward the external device, wherein the antenna module includes a substrate; a first antenna arranged on an upper surface of the substrate; and a plurality of second antennas arranged on the upper surface of the substrate to be at the same distance from the first antenna.

A method includes, when a handheld device is in motion within a service area to be traversed by a robot: obtaining ultra-wideband (UWB) ranging measurements between the handheld device and multiple anchors located in the service area; and obtaining image data and inertial measurement unit (IMU) data. The method also includes determining a trajectory of motion of the handheld device based on the UWB ranging measurements. The method also includes adjusting the trajectory based on image features obtained from the image data and motion estimates obtained from the IMU data. The method also includes identifying the adjusted trajectory as a boundary of the service area.

A robotic surgical system includes a robotic surgical assembly and a control assembly. The robotic surgical assembly includes a robotic actuation assembly, a processing device, and a first communication device. The robotic actuation assembly includes a robotic arm. The processing device is configured to instruct the robotic actuation assembly to perform a task based on a set of instructions. The first communication device is operable to transfer the set of instructions to the processing device. The control assembly includes a second communication device and a user input device. The second communication device is operable to communicate the set of instructions to the first communication device. The user input device assembly is configured to generate the set of instructions and send the set of instruction to the second communication device. At least a portion of the instructions are based on positioning of the user input device within three-dimensional space.

A method and system for autonomous picking or put-away of items, totes, or cases within a logistics facility. The system includes a remote server and at least one manipulation robot. The system may further include at least one transport robot. The remote server is configured to communicate with the various robots to send and receive picking data, and the various robots are configured to autonomously navigate and position themselves within the logistics facility.