Disclosed are various embodiments of a three-dimensional perception and object manipulation robot gripper configured for connection to and operation in conjunction with a robot arm. In some embodiments, the gripper comprises a palm, a plurality of motors or actuators operably connected to the palm, a mechanical manipulation system operably connected to the palm, a plurality of fingers operably connected to the motors or actuators and configured to manipulate one or more objects located within a workspace or target volume that can be accessed by the fingers. A depth camera system is also operably connected to the palm. One or more computing devices are operably connected to the depth camera and are configured and programmed to process images provided by the depth camera system to determine the location and orientation of the one or more objects within a workspace, and in accordance therewith, provide as outputs therefrom control signals or instructions configured to be employed by the motors or actuators to control movement and operation of the plurality of fingers so as to permit the fingers to manipulate the one or more objects located within the workspace or target volume. The gripper can also be configured to vary controllably at least one of a force, a torque, a stiffness, and a compliance applied by one or more of the plurality of fingers to the one or more objects.

A method for use with a multibody system includes two body sections assembled via a joint, one of the body sections including a camera which is moveable between a first position and a second position, includes detecting a reference object with the camera situated in the first position, determining a reference value of the reference object, requesting movement of the camera from the first position into the second position, initiating movement of the camera from the first position towards the second position, while iteratively sampling image of the reference object, determining a current object value of the reference object, based on the sampled image, matching the reference value with the current object value, and determining successfulness of the camera movement, based on the matching.

A calibration pod for calibrating a robotic wafer pod handling apparatus includes a pod body configured for handling by the robotic pod handling apparatus, at least one laser disposed on a bottom of the pod body, and a power module disposed on or in the pod body and operatively connected to power the at least one laser. In a manufacturing method, the pod body comprises a wafer carrier for carrying a cassette of semiconductor wafers, which has a bottom with a plurality of holes for aligning placement of the wafer carrier in a load port of a semiconductor device fabrication facility. The at least one laser here includes a plurality of lasers corresponding to the plurality of holes in the bottom of the wafer carrier, and each laser is mounted in a respective hole of the bottom of the wafer carrier.

Disclosed herein are implementations that relate to determining tactile information using encoders coupled to one or more fingers of a robotic gripping device. The robotic gripping device may include a finger. The finger may include a deformable front face, a base link, a first encoder, and a second encoder. The first encoder may be coupled to the base link of the finger, and configured to detect a grip angle of the finger while the robotic gripping device is gripping an object. The second encoder may be coupled to the deformable front face of the given finger, proximate to the base link of the finger. Additionally, the second encoder may be configured to detect a bend angle of the deformable front face of the finger while the robotic gripping device is gripping the object.

A position and an orientation of an object are measured with high accuracy. An approximate position-orientation of a target object is obtained, positional information of the target object is obtained by measuring the target object using a noncontact sensor, positional information of contact positions touched by a contact sensor is obtained by bringing the contact sensor into contact with the target object, and a position-orientation of the target object is obtained by associating shape information of the target object with the positional information of the target object and the positional information of the contact positions in accordance with the approximate position-orientation.

Provide is a robot and a control method thereof in which the motion of an arm 12 as a specified limb among a plurality of limbs 12 and 14 extended from a body 10 is controlled according to a specified trajectory. If a first interaction state, in which a hand 126, which is an end effector, interacts with a horizontal wood member L (j) of a ladder L in a first mode is implemented, then a control command is given to an actuator 41 that drives the hand 126 to cause the hand 126 to perform a grasping motion, thereby implementing a second interaction state, in which the hand 126 interacts with the horizontal wood member L (j) in a second manner. If the second interaction state is implemented, a control command is given to a brake 42 to maintain a motion halt state of the hand 126.

Disclosed are various embodiments of a three-dimensional perception and object manipulation robot gripper configured for connection to and operation in conjunction with a robot arm. In some embodiments, the gripper comprises a palm, a plurality of motors or actuators operably connected to the palm, a mechanical manipulation system operably connected to the palm, a plurality of fingers operably connected to the motors or actuators and configured to manipulate one or more objects located within a workspace or target volume that can be accessed by the fingers. A depth camera system is also operably connected to the palm. One or more computing devices are operably connected to the depth camera and are configured and programmed to process images provided by the depth camera system to determine the location and orientation of the one or more objects within a workspace, and in accordance therewith, provide as outputs therefrom control signals or instructions configured to be employed by the motors or actuators to control movement and operation of the plurality of fingers so as to permit the fingers to manipulate the one or more objects located within the workspace or target volume. The gripper can also be configured to vary controllably at least one of a force, a torque, a stiffness, and a compliance applied by one or more of the plurality of fingers to the one or more objects.

A method for automatically calibrating the position of a wafer handling robot relative to a wafer carrier. The method comprises providing a semiconductor processing assembly comprising the wafer carrier and the wafer handling robot having an end effector, placing a wafer on a wafer support surface of the end effector, moving the end effector to an end position adjacent the wafer carrier, determining a displacement of the wafer on the wafer support surface, repeating these steps until the magnitude of the displacement meets a set end criterion, and storing the latest used end position as a calibrated end position.

A computer-implemented method, executed by data processing hardware of a robot, includes receiving a three-dimensional point cloud of sensor data for a space within an environment about the robot. The method includes receiving a selection input indicating a user-selection of a target object represented in an image corresponding to the space. The target object is for grasping by an end-effector of a robotic manipulator of the robot. The method includes generating a grasp region for the end-effector of the robotic manipulator by projecting a plurality of rays from the selected target object of the image onto the three-dimensional point cloud of sensor data. The method includes determining a grasp geometry for the robotic manipulator to grasp the target object within the grasp region. The method includes instructing the end-effector of the robotic manipulator to grasp the target object within the grasp region based on the grasp geometry.

To perform a start-up operation of robots more simply than conventionally. A programming device includes: a program generation unit that generates a program for causing a predetermined operation passing through a plurality of movement destination points to be executed by a robot; a robot control unit that causes the predetermined operation to be executed by the robot according to control based on the program; an image acquisition unit that acquires a photographed image capturing a reference point that is arranged at a position having a predetermined relative relationship with a position of the movement destination point; and a movement destination point correction unit that corrects information of the movement destination point included in the program, based on the photographed image and the predetermined relative relationship, in which the robot control unit controls the robot based on corrected information of the movement destination point.