A system for verifying quality of a part using an arm robot includes an arm robot, which includes a camera to acquire image data of a part assembled in each manufacturing process of a vehicle, a carrier, which includes a sliding rail allowing the arm robot to be movable around the vehicle along the sliding rail to acquire the image data, and a server which receives the image data acquired by the camera, compares the image data with modeling data of the vehicle, which is stored in a database, and determines whether the assembled part satisfies a preset inspection item, to verify quality of the assembled part, verifying the quality of the part in each process before the vehicle is completely manufactured.

A system includes a robotic system including a robot disposable at a mobile workstation, where the robot is configured to perform an automated operation on a workpiece. The system includes one or more transfer robots configured to transfer the robotic system to or from the mobile workstation. The system includes a control system configured to command the transfer robot to perform a transfer operation of the robotic system, where the transfer operation includes at least one of disposing the robotic system at the mobile workstation or retrieving the robotic system from the mobile workstation. The control system is configured to control the mobile workstation and the robotic system based on image data from the one or more infrastructure sensors, position data from the one or more on-board position sensors, the automated operation to be performed by the robot, or a combination thereof.

In variants, a method for robot control can include: receiving sensor data of a scene, modeling the physical objects within the scene, determining a set of potential grasp configurations for grasping a physical object within the scene, determining a reach behavior based on the potential grasp configuration, determining a trajectory for the reach behavior, and grasping the object using the trajectory.

A mobile manipulator robot for retrieving inventory items from a storage system. The robot includes a body, a wheel assembly, a sensor to locate a position of the robot within the storage system, an interface configured to send processor readable data to a remote processor and to an operator interface, and receive processor executable instructions from the remote processor and from the operator interface, an imaging device to capture images of the inventory items, a picking manipulator, first and second pneumatic gripping elements for grasping the inventory items, and a coupler configured to mate with a valve to access a pneumatic supply for operating at least one of the first or second pneumatic gripping elements. The robot is configured to transition the valve from a closed condition to an open condition and selectively place one of the first or the second pneumatic gripping elements in communication with the pneumatic supply.

A robotic system for use with a payload includes a robot, a passive compliance mechanism, position sensors, and an electronic control unit (ECU). Actuated joints of the robot provide the robotic system with actuated degrees of freedom (DOF). The compliance mechanism is connected to the robot and payload, and has unactuated joints providing the robotic system with unactuated DOF. The sensors measure joint positions of the joints. The ECU has a trajectory generator block which generates a payload trajectory signal in response to dynamic control inputs, and an impedance control unit (ICU) applying damping and stiffness parameters to the payload trajectory signal to generate an initial velocity command. A stiction compensation block allows the robotic system to generate a velocity offset, and applies the velocity offset to the initial velocity command to produce a final velocity command for the robot.

In an aspect of the disclosure, a first manufacturing cell for assembling a structure is provided. The first manufacturing cell for assembling the structure may include a plurality of first robots positioned around a common point in a first configuration, and a plurality of second robots positioned around the common point in a second configuration, the second configuration being closer to the common point than the first configuration. One of the plurality of first robots is configured to translate towards and away from the common point to interact with one of the plurality of second robots or one of the plurality of second robots is configured to translate towards and away from the common point to interact with one of the plurality of first robots.

A system and method for operating at least one stowable automated robotic pod in a workplace having a workpiece is disclosed. The pod includes a robot on a base that can also include one or both of a tool nest and process equipment. A door to subfloor storage allows the pod to raise its base vertical, placing the robot into the desired vertical position in the workspace. Once operations on the workpiece are complete, the pod withdraws back to the subfloor storage and the doors to the storage volume close.

A storage system configured to house a plurality of containers housing inventory items includes support members, a first set of parallel rails to support a mobile, manipulator robot, and a fluid supply line having a plurality of valves disposed within the fluid supply line. Each of the valves having a closed condition in which the supply line is in fluid isolation from an outside environment and an open condition in which the supply line is in fluid communication with the environment such that the supply line is configured to supply fluid to a mobile, manipulator robot. Mobile, manipulator robots for retrieving inventory items stored within the containers and retrieval methods are also disclosed herein.

A system comprises a database; at least one hardware processor coupled with the database; and one or more software modules that, when executed by the at least one hardware processor, receive at least one of sensory data from a robot and images from a camera, identify and build models of objects in an environment, wherein the model encompasses immutable properties of identified objects including mass and geometry, and wherein the geometry is assumed not to change, estimate the state including position, orientation, and velocity, of the identified objects, determine based on the state and model, potential configurations, or pre-grasp poses, for grasping the identified objects and return multiple grasping configurations per identified object, determine an object to be picked based on a quality metric, translate the pregrasp poses into behaviors that define motor forces and torques, communicate the motor forces and torques to the robot.

A system comprising: a database configured to store a multi-body model of a robot, the robot comprising a plurality of manipulators, and a plurality of joints and plurality of actuators and actuator motors configured to move the joints, and wherein the multi-body model includes a kinematic and geometric model of each manipulator, a catalog of models for objects to be manipulated, the models comprising a current configuration and a target configuration, and a functional mapping of sensory data to configurations of the robot and the manipulators needed to manipulate the objects; at least one hardware processor coupled with the database; and one or more software modules that, when executed by the at least one hardware processor, receive sensory data from within a constrained space, identify objects in the constrained space based on the received sensory data and the catalog of models, determine a target pose for the joints and the manipulators based on the sensory data and the current and target configurations associated with the identified object, and compute joint space positions to necessary to realize the target pose.