A control system 1 includes a first controller, and a second controller. The second controller includes a program storage module that stores two or more coordinate conversion programs, and a control processing module 240 that acquires program designation information for designating one of two or more coordinate conversion programs from the first controller. Additionally, the control processing module may acquire a first operation command in the coordinate system for the first controller from the first controller, and convert the first operation command to an operation target value of two or more joint axes of a multi-axis robot using the coordinate conversion programs according to the program designation information. Driving power according to the operation target value may be output to the joint axes.

A manipulator configured to navigate a heat exchanger including a plurality of tubes extending through a tubesheet is disclosed herein, the manipulator including a first end effector, a second end effector, and an articulation assembly. The first end effector is configured to accommodate an instrument configured to service the heat exchanger and includes a first actuator configured to extend a first gripper into a tube of the plurality of tubes. The second end effector includes a second actuator configured to extend a second gripper into a tube of the plurality of tubes. The first and second gripper are configured to secure the manipulator to the tubesheet, and, when the second gripper is securing the manipulator to the tubesheet, the articulation assembly is configured to enable the first end effector to move relative to the second end effector in a plane that is parallel to the tubesheet.

A robotic PV module installation system for populating a solar generation plant with PV modules with minimal human intervention. The PV module installation system can include an aerial work platform (AWP), a linear slide, and a robotic arm. The AWP can include an articulated boom. The AWP can also be configured for movement over off-road terrain. The linear slide can be coupled to a free-end of the articulated boom. The robotic arm can be coupled to a slide of the linear slide to increase a horizontal reach of the robotic arm through movement of the slide along the linear slide. The robotic arm can also include an end of arm tooling configured to pick up PV modules.

Methods and systems are provided for providing real world assistance by a robot utility and interface device (RUID) are provided. A method provides for identifying a position of a user in a physical environment and a surface within the physical environment for projecting an interactive interface. The method also provides for moving to a location within the physical environment based on the position of the user and the surface for projecting the interactive interface. Moreover, the method provides for capturing a plurality of images of the interactive interface while the interactive interface is being interacted with by the use and for determining a selection of an input option made by the user.

An installing device includes a connection member and a linear motion support. The connection member is disposed at a base end portion of a hollow arm which extends in an extension direction and which has a hollow extending in the extension direction. A linear object passing through the hollow is connectable to the connection member. The linear motion support supports the connection member slidably with respect to the hollow arm in the extension direction.

This disclosure relates generally to a mobile robotic manipulator with telepresence system which includes a chassis assembly, a tilting arm assembly, and a rotary gripper assembly. The chassis assembly includes a chassis plate which mounts plurality of drive motors coupled with plurality of omni wheels through plurality of L mounting brackets; plurality of anti-toppling arms includes a plurality of linear guides which is mounted on a C mount plate; and plurality of linear actuators is mounted to expand or retract the plurality of anti-toppling arms. The tilting arm assembly includes a bottom fixed end of a front long actuator is mounted to a large rotating plate through plurality of C clamps. The rotary gripper assembly includes a top plate of a gripper is mounted and separated by gap with a bottom plate of the gripper to place a gripper actuator on top surface of the bottom plate of the gripper.

A robot has a base, a first arm provided at the base and pivoting about a first axis relative to the base, a second arm provided at the first arm and pivoting about a second axis parallel to the first axis relative to the first arm, an inertial sensor provided in the second arm and detecting one or both of an angular velocity about an angular velocity detection axis orthogonal to an axial direction of the second axis and an acceleration in the second axis direction, a pipe located outside of the first arm and coupling the base and the second arm, and a wire placed through the pipe and electrically coupled to the inertial sensor.

A robotic arm for automatically displacing an object between two locations based on a combination of pre-set instructional data and dynamically updated instructional data includes a robotic arm sensor for detecting objects located within a distance D.sub.rs from a reference point on the robotic arm and, the robotic arm sensor is configured to determine, based on receiving signals from the detected object, at least one of the distance to the detected object, the size of the detected object, and at least one physical property of the detected object.

A robotic system comprising a mobile chassis, a conveyor oriented substantially parallel to a longitudinal axis of the chassis, one or more robotic arms disposed adjacent to the conveyor, and one or more cameras positioned to view at least a portion of a top surface of the conveyor is disclosed. The system uses the mobile chassis, the conveyor, and the robotic arms to load items into a truck or other container, including by using image data generated by the one or more cameras to assess a state of items on the top surface of the conveyor; determine based at least in part on the image data that an additional item is to be added to the top surface of the conveyor; and operate a robotically controlled structure to cause an item to be added to the top surface of the conveyor.

A positioning apparatus with a pose measurement function includes a first and second kinematic links, a first measuring link attached to the second kinematic link, a joint connecting the first and second kinematic links, and a sensor capturing a measurement device. Either the measurement device or the sensor is arranged at the first measuring link and is movable jointly with the second kinematic link. The other one is arranged at the first kinematic link and is movable jointly with the first kinematic link. An attachment location of the first measuring link lies closer to an end of the second kinematic link that is remote from the joint than to the joint. The positioning apparatus is configured to ascertain, based on data captured by the sensor, a first relative pose value corresponding to the degree of freedom of the joint and a further relative pose value for another degree of freedom.