According to at least one aspect, the present disclosure provides a robot system for automatically assembling a modular component and an assembly target, comprising: an assembly robot including a first manipulator, an assembly tool coupled to the first manipulator and configured to assemble the modular component and the assembly target, and a first camera configured to capture images in a direction in which the assemble tool faces; a loading robot including a second manipulator and a gripper coupled to the second manipulator and configured to grip the modular component; and a control device configured to control the assembly robot and the loading robot.

Disclosed are a method and system for assembling a vehicle component, the system including an image capturing unit configured to capture an image of a mounted vehicle component and an image of an assembly point on a vehicle to which the vehicle component is assembled, an assembly robot configured to load the mounted vehicle component, move the loaded vehicle component to the assembly point on the vehicle, and assemble the vehicle component to the assembly point, and a control unit configured to analyze the image of the vehicle component captured by the image capturing unit, control the assembly robot to allow the assembly robot to load the mounted vehicle component at the same point, analyze the image of the assembly point on the vehicle, and control the assembly robot to allow the assembly robot to assemble the vehicle component accurately to the assembly point of the vehicle.

Various embodiments described herein relate to techniques for object height detection for palletizing operations and/or depalletizing operations. In this regard, an automated industrial system comprises at least a column portion, a robot arm portion, and an end effector configured to grasp an object. An image-capturing device is mounted onto the automated industrial system and is configured to rotate, based on movement of the robot arm portion, to scan the object grasped by the end effector and to generate image-capturing data associated with the object. Furthermore, a processing device is configured to determine height data for the object based on the image-capturing data. The processing device is also configured to determine location data for the object with respect to a conveyor system based on the height data.

Techniques for corrugate and chipboard knocked-down case inspection and assembly are described herein. In one example, the disclosed techniques include a method to inspect and assemble a knocked-down case. In the example, a measurement of at least one aspect of the knocked-down case is obtained. A difference is determined between the obtained measurement and a standard measurement and/or a range of standard measurements. Programming of a case-handling tool is executed that is based at least in part on the determined difference. In an example, the programming is configured to adjust for and/or compensate for differences between the actual knocked-down case and a knocked-down case that is within a specification. A case-handling tool is operated responsive to the executed programming to at least partially erect the knocked-down case into an erected case.

A robot control system includes a relative relationship calculating section configured to calculate a relative relationship between a first member and a second member at least at one of a plurality of points based on data acquired by a vision sensor, a contact point determination section configured to determine a contact point between the first member and the second member based on the calculated relative relationship, a control point setting section configured to set a control point based on the determined contact point, and a fitting control section configured to control fitting of the plurality of points based on the set control point.

A portable device repair machine may be configured to receive portable devices, identify the portable device, diagnose, repair and/or upgrade the portable device, collect payment for the service and return the portable device to the payee. The portable device repair machine may include an audio/video interface for interaction with a portable device user as well as a mechanized connection, inspection, diagnostic and upgrade system. The mechanized connection, inspection, diagnostic and upgrade system may comprise a conveyance mechanism for conveying the portable device among multiple stations such as a physical inspection station, device connection mechanism station, diagnostic, repair and upgrade station, and a physical upgrade station. Various mechanical devices, such as robotic arms may interact with the portable device, based in part on feedback obtained via various image sensors within the portable device repair machine.

A remote control manipulator system includes a manipulator controlled remotely by an operator; a camera to capture an image including the manipulator; a posture sensor to detect posture data; an action instruction inputter with which the operator inputs an action instruction instructing action to move or stop the manipulator; a control device including a structural data storage to store manipulator structural data representing a structure of the manipulator, a model image generator to generate a model image with referring to the structural data storage and the posture data, and a presentation image generator to generate a presentation image by superimposing a model image on the captured image; and a display to display the presentation image.

An inventory management system includes pick stations, automated vehicles having an onboard power source, a first drive system configured to horizontally displace the vehicle, a second drive system configured to vertically displace the vehicle along a guide system, and a platform for supporting an item during displacement of the vehicle. A first plurality of storage locations store inventory items at a first zone of vehicle operation and a second plurality of storage areas store inventory items at a second zone of vehicle operation. A first pick station is closer to the first storage locations than to the second storage locations, Vehicles are configured to transfer a selected item from one of the second plurality of storage locations to the first pick station or to transfer the selected item from the second plurality of storage locations to the first plurality of storage locations.

Embodiments of the present disclosure provide a robot arm apparatus including a fastener for fastening a first electronic component to a second electronic component, and a movable part configured to move the fastener. The fastener includes an arm connected to the movable part, a head connected to the arm and configured to contact the first electronic component, and a lock configured to be in contact with the arm when the first electronic component is moved to a reference space, and to be spaced apart from the arm when the first electronic component is fastened to the second electronic component after the first electronic component is moved to the reference space.

A method and computing system for transferring objects between a source repository and a destination repository is provided. The computing system is configured to operate by a combination of pre-planned and image base trajectories to improve speed and reliability of object transfer. The computing system is configured to capture image information of repositories and use the captured information to alter or adjust pre-planned trajectories to improve performance.