A teleoperated robotic system that includes master control arms, slave arms, and a mobile platform. In use, a user manipulates the master control arms to control movement of the slave arms. The teleoperated robotic system can include two master control arms and two slave arms. The master control arms and the slave arms can be mounted on the platform. The platform can provide support for the master control arms and for a teleoperator, or user, of the robotic system. Thus, a mobile platform can allow the robotic system to be moved from place to place to locate the slave arms in a position for use. Additionally, the user can be positioned on the platform, such that the user can see and hear, directly, the slave arms and the workspace in which the slave arms operate.

A vehicle or another object is grasped by a robotic arm of a handling system and caused to undergo one or more movements or manipulations resulting in a change of position, orientation, velocity or acceleration of the vehicle. Sensors provided in the robotic arm capture data representative of forces or torques imparted upon the robotic arm by the vehicle during or after the movement, or power or energy levels of vibration resulting from the movement. A signature representative of an inertial or vibratory response of the vehicle to the movement is derived based on the data. The signature may be compared to a baseline signature similarly derived for a vehicle that is known to be structurally and aerodynamically sound. If the signature is sufficiently similar to the baseline signature, the vehicle may also be determined to be structurally and aerodynamically sound.

Systems and methods relating to generations of models to facilitate safe, automated handling and maneuvering of vehicles, such as unmanned aerial vehicles (UAV), by robotic systems, such as a robotic arm. The described systems and methods can include a robotic system, such as a robotic arm, having a load cell to measure certain forces and torques to generate models representing the behavior of vehicles and surfaces on which the vehicles may be placed and/or from which the vehicles may be removed.

The present specification relates to a mobile robot system and a method for generating boundary information of the mobile robot system, wherein the mobile robot system generates first map data for the locations of a plurality of transmitters installed in a driving area on the basis of the result of receiving the transmission signals from the plurality of transmitters, receives second map data for an area corresponding to the driving area from a communication target means in which map information of an area including the driving area is stored, and matches the first map data and the second map data to generate boundary information about a boundary area of the driving area.

A computer-implemented method executed by data processing hardware of a robot causes the data processing hardware to perform operations. The operations include receiving a sensor pointing command that commands the robot to use a sensor to capture sensor data of a location in an environment of the robot. The sensor is disposed on the robot. The operations include determining, based on an orientation of the sensor relative to the location, a direction for pointing the sensor toward the location, and an alignment pose of the robot to cause the sensor to point in the direction toward the location. The operations include commanding the robot to move from a current pose to the alignment pose. After the robot moves to the alignment pose and the sensor is pointing in the direction toward the location, the operations include commanding the sensor to capture the sensor data of the location in the environment.

A mobile vehicle having an AOI dynamic inspection system with multi-angle visual quality includes a base body, two driving bracket, two connecting rod assemblies and an arm member and a working portion. The arm member is swingably disposed on the base body. The working portion is disposed on one end of the arm member which is remote from the base body. The working portion includes a first photographing device. The first photographing device is configured for capturing an image of an object. At least two second photographing devices is configured to be disposed in an environment and configured for capturing an image of the object.

Systems and methods for process tending with a robot arm are presented. The system comprises a robot arm and robot arm control system mounted on a self-driving vehicle, and a server in communication with the vehicle and/or robot arm control system. The vehicle has a vehicle control system for storing a map and receiving a waypoint based on a process location provided by the server. The robot arm control system stores at programs that is executable by the robot arm. The vehicle control system autonomously navigates the vehicle to the waypoint based on the map, and the robot arm control system selects a target program from the stored programs based on the process location and/or a process identifier.

A control method includes an input step for inputting information concerning a setting angle for a robot arm of a robot, the robot including the robot arm and a force detecting section that detects force applied to the robot arm, and a calculating step for calculating, based on a first force detection parameter of the force detecting section corresponding to setting at a first setting angle for the robot arm and a second force detection parameter of the force detecting section corresponding to setting at a second setting angle different from the first setting angle for the robot arm, a third force detection parameter of the force detecting section at the setting angle for the robot arm.

Provided is a management system for managing storage and retrieval of items. The management system includes a transfer robot that includes a drive mechanism and a sensor, the drive mechanism being configured to move a shelf along a transfer route to a region where any one of operations of carrying in an item, carrying out the item, and transferring the item between shelves is enabled to be performed, and place the shelf at a predetermined position, the sensor being configured to detect a position of the transfer robot in a space where the transfer robot is allowed to be moved, a device configured to perform at least either the operation or assistance in the operation, and a first controller configured to generate control data for controlling the device and output the control data to the device, the control data being generated on the basis of an error between a position of the shelf transferred by the transfer robot and a target position on the transfer route, the error being calculated by using the position of the transfer robot detected by the sensor.

A robot includes a robot body, a hand, an arm, and a controller. The hand includes a fixed frame that is fixed to the arm, a first camera that is attached to the fixed frame, a movable frame that is rotatable with respect to the fixed frame, gripping portions that are attached to the movable frame to grip an article having a front surface facing the robot and a back surface opposite to the front surface, and a driver that rotates the movable frame. The gripping portions grip the article in a state where the back surface is opened, and shift from a first state where the article is gripped to a second state where the back surface of the article is able to be captured by the first camera by the rotation of the movable frame.