A tool and system for inspecting, handling, sorting, and packing a sealable bag, the tool including: a housing which includes a mount for mechanically mounting the tool to a tip end of a robot arm; at least four displaceable fingers fixed to the housing in a configuration corresponding to dimensions of the sealable bag, each displaceable finger being displaceable in an axial direction of the displaceable finger and having a sensor for sensing displacement of the displaceable finger by more than a predetermined amount; a suction mechanism fixed to the housing and actuatable to lift the sealable bag; and a controller in communication with the sensor and with the suction mechanism.

An object gripping mechanism is provided for use with a robotic arm. A robotic arm and method of manufacturing an object gripping mechanism are also provided. The object gripping mechanism includes an attachment modular configured to connect the object gripping mechanism to the robotic arm. The object gripping mechanism also includes a plurality of retractable arms each pivotably connected with the attachment modular. The object gripping mechanism also includes one or more movement mechanisms collectively configured to pivot the plurality of retractable arms to a desired position. The object gripping mechanism further includes a drive mechanism positioned within each of the plurality of retractable arms and configured to pivot the object engagement feature using a gear and timing belt configuration.

The present disclosure relates generally to a container tray for harvesting a plurality of commercially cultivated button-type mushrooms. The present disclosure discusses a mushroom harvesting container tray that cannot only be used for temporarily storing the harvested (picked) mushrooms during the harvesting (picking) process, but the tray can also effectively store and retain the untrimmed mushrooms in place during trimming such that the mushroom stems may be trimmed while being housed in the tray, thereby substantially increasing the efficiency of harvesting mushrooms. For example, the tray holds the mushroom steady while a blade or other cutting mechanism simultaneously trims a plurality of mushroom stems. The present disclosure also relates to a sorting device that determines whether the mushrooms are acceptable and removes the acceptable mushrooms from the tray after the stems have been cut and simultaneously sorts the acceptable mushrooms according to their respective size, shape, color, weight and/or other feature, while also separating or rejecting the unacceptable mushrooms.

A system and method for motion planning is presented. The system is configured, when an object is or has been in a camera field of view of a camera, to receive first image information that is generated when the camera has a first camera pose. The system is further configured to determine, based on the first image information, a first estimate of the object structure, and to identify, based on the first estimate of the object structure or based on the first image information, an object corner. The system is further configured to cause an end effector apparatus to move the camera to a second camera pose, and to receive second image information for representing the object's structure. The system is configured to determine a second estimate of the object's structure based on the second image information, and to generate a motion plan based on at least the second estimate.

Methods, apparatuses, systems, and computer program products for an improved anti-sway control system and adjustable end effector for a robotic arm are provided. An example method includes determining at least one of a size, shape or orientation of a package to be picked up by an end effector of a robotic arm and facilitating adjusting a position of a suction cup on the end effector, wherein the position is determined based on the at least one determined size, shape, or orientation of the package. The method further includes facilitating grasping the package with the end effector and facilitating movement of the end effector via a robotic joint to reduce force on the suction cup by the package due to an acceleration of the package due to movement of the robotic arm.

A robotic system is provided. The robotic system may include an end-effector configured for grasping an object, a sensor unit monitoring contact information received from the contact limit sensor, and a controller, coupled to the sensor unit. The end-effector may include a suction cup assembly for engaging the object, and a contact limit sensor for detecting a pressure associated with the engagement between the suction cup assembly and the object, wherein the contact limit sensor transmits contact information when the contact limit sensor detects the pressure exceeding a contact threshold. The controller may execute an operation for controlling the end-effector to limit movement of the end-effector toward the object based on the contact information received to prevent damage to the object.

A system and method for motion planning is presented. The system is configured, when an object is or has been in a camera field of view of a camera, to receive first image information that is generated when the camera has a first camera pose. The system is further configured to determine, based on the first image information, a first estimate of the object structure, and to identify, based on the first estimate of the object structure or based on the first image information, an object corner. The system is further configured to cause an end effector apparatus to move the camera to a second camera pose, and to receive second image information for representing the object's structure. The system is configured to determine a second estimate of the object's structure based on the second image information, and to generate a motion plan based on at least the second estimate.

A method and computing system for performing object detection are presented. The computing system may be configured to: receive first image information that represents at least a first portion of an object structure of an object in a camera's field of view, wherein the first image information is associate with a first camera pose; generate or update, based on the first image information, sensed structure information representing the object structure; identify an object corner associated with the object structure; cause the robot arm to move the camera to a second camera pose in which the camera is pointed at the object corner; receive second image information associated with the second camera pose; update the sensed structure information based on the second image information; determine, based on the updated sensed structure information, an object type associated with the object; determine one or more robot interaction locations based on the object type.

A workpiece holding device includes a plurality of holding claws configured to hold a workpiece, and holding cylinders as claw opening/closing members configured to displace the holding claws in a direction closer to or away from a first workpiece. The holding cylinders are provided for the holding claws, respectively. Therefore, the plurality of holding claws can be opened/closed individually. The holding cylinders are held on a support disk as a holding member in a movable manner. That is, by moving the holding cylinders to arbitrary positions on the support disk, the holding cylinders are positioned fixedly.

A gripping device (2) configured to be detachably attached to a robot (20). The gripping device (2) comprises one or more extremities (10, 10′) provided with one or more suction members (12, 12′) connected to a vacuum source (18). At least two of the extremities (10, 10′) are rotatably arranged with respect to each other