Abstract: One approach is directed to a robotic package handling system, comprising a robotic arm comprising a distal portion and a proximal base portion; an end effector coupled to the distal portion of the robotic arm; a place structure in geometric proximity to the distal portion of the robotic arm; a pick structure transiently coupled to one or more packages and positioned in geometric proximity to the distal portion of the robotic arm; a first imaging device positioned and oriented to capture image information pertaining to the pick structure and one or more packages; and a first computing system operatively coupled to the robotic arm and the first imaging device, and configured to receive the image information from the first imaging device and command movements of the robotic arm based at least in part upon the image information.

Abstract: An end effector device and system for suction-based grasping of bagged objects that can include a body structure with a vacuum line opening and an object engagement region, the vacuum line opening being configured to couple at least one pressure line of a vacuum pressure system to a defined internal channel of the body structure; the body structure comprising an internal structure that defines a concave inner chamber with a chamber opening at the object engagement region; and the internal structure comprising an array of inlets positioned along at least one wall of the concave inner chamber, wherein each inlet defines an opening in the body to the defined internal channel.

Abstract: An end effector device and system for suction-based grasping of bagged objects that can include a body structure with a vacuum line opening and an object engagement region, the vacuum line opening being configured to couple at least one pressure line of a vacuum pressure system to a defined internal channel of the body structure; the body structure comprising an internal structure that defines a concave inner chamber with a chamber opening at the object engagement region; and the internal structure comprising an array of inlets positioned along at least one wall of the concave inner chamber, wherein each inlet defines an opening in the body to the defined internal channel. The body structure may additionally include a suction cup system that comprises a flexible sealing lip at the object engagement region; wherein the chamber opening being positioned within a grasping region of the sealing lip.

Abstract: One embodiment is directed to robotic package handling system, comprising: a. a robotic arm comprising a distal portion and a proximal base portion; b. an end effector coupled to the distal portion of the robotic arm; c. a place structure positioned in geometric proximity to the distal portion of the robotic arm; d. a pick structure in contact with one or more packages and positioned in geometric proximity to the distal portion of the robotic arm; e. a first imaging device positioned and oriented to capture image information pertaining to the pick structure and one or more packages; f.

Abstract: A system and method for item sorting that can include an item selection unit with a robotic pick-and-place machine positioned adjacent to a defined input item region; an item sortation unit comprising a horizontal multi-degree-of-freedom gantry system and an item tote array, wherein the horizontal gantry system is positioned above the item tote array; wherein the item sortation unit further comprises an item holding and depositing system that is coupled to and actuated by the gantry system. The system and method can singulate an item from a collection of items and sort into one of a set of item totes.

Abstract: A system and method for a dynamic robot kitting line that can include: processing a set of order requests and setting a packing fulfillment plan process for a robotic kitting line, wherein robotic kitting line comprises a conveyor system, a set of robotic workcells arranged along the conveyor system, and where each robotic workcell includes at least one robotic pick-and-place machine and a set of item bins; and managing operation of the robotic kitting line according to the packing fulfillment plan, which includes: conveying item totes through the set of robotic workcells, and for each item tote, progressively packing items of an order request assigned to an item tote by incrementally packing items at robotic workcells of the set of robotic workcells.

Abstract: An end effector device and system for suction-based grasping of bagged objects that can include a body structure with a vacuum line opening and an object engagement region, the vacuum line opening being configured to couple at least one pressure line of a vacuum pressure system to a defined internal channel of the body structure; the body structure comprising an internal structure that defines a concave inner chamber with a chamber opening at the object engagement region; and the internal structure comprising an array of inlets positioned along at least one wall of the concave inner chamber, wherein each inlet defines an opening in the body to the defined internal channel. The body structure may additionally include a suction cup system that comprises a flexible sealing lip at the object engagement region; wherein the chamber opening being positioned within a grasping region of the sealing lip.

Abstract: An end effector device and system for suction-based grasping of bagged objects that can include a body structure with a vacuum line opening and an object engagement region, the vacuum line opening being configured to couple at least one pressure line of a vacuum pressure system to a defined internal channel of the body structure; the body structure comprising an internal structure that defines a concave inner chamber with a chamber opening at the object engagement region; and the internal structure comprising an array of inlets positioned along at least one wall of the concave inner chamber, wherein each inlet defines an opening in the body to the defined internal channel.

Abstract: According to some embodiments of the invention, an adjusting device for adjusting a passive drip irrigation valve to enable precision irrigation includes a device body configured to be at least one of hand-held or attachable to a robot, the device body having a manipulator end, and a manipulator assembly contained within and extending from the manipulator end of the device body. The manipulator assembly includes a coarse alignment adjustment assembly constructed and arranged to align the adjusting device with the passive drip irrigation valve. The manipulator assembly also includes a fine actuator configured to rotate the passive drip irrigation valve by a specified angle.

Abstract: A compliant robot includes a base and a compliant robot arm. The compliant robot arm includes a first quasi-direct drive assembly operatively connected to said base such that said compliant robot arm has at least one degree of freedom for motion relative to said base. The first quasi-direct drive assembly provides passive compliance such that said compliant robot arm has a back-drivable mode of operation for interactions between said compliant robot arm and an environment.

Abstract: According to some embodiments of the invention, an adjusting device for adjusting a passive drip irrigation valve to enable precision irrigation includes a device body configured to be at least one of hand-held or attachable to a robot, the device body having a manipulator end, and a manipulator assembly contained within and extending from the manipulator end of the device body. The manipulator assembly includes a coarse alignment adjustment assembly constructed and arranged to align the adjusting device with the passive drip irrigation valve. The manipulator assembly also includes a fine actuator configured to rotate the passive drip irrigation valve by a specified angle.