Abstract: Autonomous ground vehicles (“AGVs”) are utilized to transport ordered items and may congregate in meeting areas (e.g., to receive items from common sources, utilize common resources, communicate, etc.) and the positions of the AGVs in an area may be coordinated. For example, AGVs waiting to receive ordered items from a transportation vehicle (e.g., a delivery truck) may be lined up according to delivery addresses, or according to an order of items in the transportation vehicle, etc. As another example, AGVs that are in a pickup area (e.g., where users may retrieve ordered items from the AGVs), may be arranged in a configuration that is relatively compact but which provides easy access for the users to retrieve the ordered items, etc. The AGVs may be repositioned based on various events (e.g., an AGV leaving the configuration, an improved arrangement being dynamically determined, etc.).

Abstract: Autonomous ground vehicles (“AGVs”) are utilized to retrieve items from transportation vehicles (e.g., delivery trucks) for delivery to specified locations (e.g., user residences, etc.). In various implementations, the AGVs may be owned by individual users and/or may service a group of users in a given area (e.g., in an apartment building, neighborhood, etc.). The AGVs may travel out (e.g., from a user's residence, apartment building, etc.) to meet a transportation vehicle (e.g., a delivery truck on the street) to receive items, and may be joined by other AGVs that have traveled out to meet the transportation vehicle, and may line up in a particular order (e.g., according to delivery addresses, etc.). After the items are received, the AGVs may travel back (e.g., to the user residences) to deliver the items, and may be equipped to open and close access barriers (e.g., front doors, garage doors, etc.).

Abstract: A modular sorting station includes a frame defining an inbound bay and an outbound bay, each of the inbound and outbound bays being sized to receive an inventory holder containing inventory thereon. A robotic grasper is mounted to the frame and positioned above one of the inbound and outbound bays and operable to transfer inventory items from the inbound bay to the outbound bay, and a sensor mounted to one of the frame or robotic grasper and operable to identify inventory at the inbound bay when the inventory holder is present in the inbound bay. The frame is sized and arranged to align with a material handling grid and permit drive units to transport inventory holders into and out of the inbound bay and/or outbound bays while moving along the material handling grid; and the frame is portable such that the modular sorting station can be moved as a modular unit for rapid deployment.

Abstract: An intermediary device may be configured to allow an authorized visitor to access a secure facility (such as a home) on behalf of an owner. The intermediary device may generate an authenticator and provide the authenticator to a service provider, who may then present the authenticator to the intermediary device upon arriving at the facility. The intermediary device may unlock or open, or lock and close, any doors within the facility as necessary in order to grant access to a specific portion of the facility and restrict access to other portions of the facility. The intermediary device may also capture, or cause the capture of, images or other data regarding actions taken by the service provider, and establish a communications channel with the owner for the exchange of information or data regarding such actions, or any events or conditions of the facility.

Abstract: Robotic enabled lift concepts are described. In one embodiment, a vertical lift includes a vertically directed track assembly and linear actuator that extend between first and second levels. The lift further includes a lift platform having a continuous contact roller such as a continuous belt, for example, a platform guide assembly for engagement with the track assembly, and a motion translation mechanism mechanically coupled between the continuous contact roller and the linear actuator. A robotic drive unit can drive upon and dock with the lift platform. In that docked position, the robotic drive unit can rotate its drive wheels to raise or lower itself between the first and second levels based on the translation of the motive forces of the drive wheels through the motion translation mechanism and to the vertically directed linear actuator. Other embodiments include a lift arm, an inclined track assembly, and a lift carriage.

Abstract: Robotic enabled lift concepts are described. In one embodiment, a vertical lift includes a vertically directed track assembly and linear actuator that extend between first and second levels. The lift further includes a lift platform having a continuous contact roller such as a continuous belt, for example, a platform guide assembly for engagement with the track assembly, and a motion translation mechanism mechanically coupled between the continuous contact roller and the linear actuator. A robotic drive unit can drive upon and dock with the lift platform. In that docked position, the robotic drive unit can rotate its drive wheels to raise or lower itself between the first and second levels based on the translation of the motive forces of the drive wheels through the motion translation mechanism and to the vertically directed linear actuator. Other embodiments include a lift arm, an inclined track assembly, and a lift carriage.

Abstract: Inventory management systems and related methods employ radio frequency based tracking of a worker's hands to monitor performance of inventory tasks. An inventory management system includes inventory bins, a user-wearable unit configured to be worn in proximity to a user's hand, fixed RF antennas configured to transmit at least one RF interrogation signal and receive at least one RF response signal, a RF transceiver operatively coupled with the fixed RF antennas, and a management module operatively coupled with the RF transceiver. The user-wearable unit includes an RF transceiver configured to transmit RF response signals in response to reception of the at least one RF interrogation signal. The management module is configured to process signals generated by the RF transceiver to track locations of the user-wearable unit and identify an inventory bin based on proximity of the user-wearable unit to the identified inventory bin to monitor performance of an inventory system task.

Abstract: Autonomous ground vehicles (“AGVs”) are utilized to retrieve items from transportation vehicles (e.g., delivery trucks) for delivery to specified locations (e.g., user residences, etc.). In various implementations, the AGVs may be owned by individual users and/or may service a group of users in a given area (e.g., in an apartment building, neighborhood, etc.). The AGVs may travel out (e.g., from a user's residence, apartment building, etc.) to meet a transportation vehicle (e.g., a delivery truck on the street) to receive items, and may be joined by other AGVs that have traveled out to meet the transportation vehicle, and may line up in a particular order (e.g., according to delivery addresses, etc.). After the items are received, the AGVs may travel back (e.g., to the user residences) to deliver the items, and may be equipped to open and close access barriers (e.g., front doors, garage doors, etc.).

Abstract: Inventory management systems and related methods employ radio frequency based tracking of a worker's hands to monitor performance of inventory tasks. An inventory management system includes inventory bins, a user-wearable unit configured to be worn in proximity to a user's hand, fixed RF antennas configured to transmit at least one RF interrogation signal and receive at least one RF response signal, a RF transceiver operatively coupled with the fixed RF antennas, and a management module operatively coupled with the RF transceiver. The user-wearable unit includes an RF transceiver configured to transmit RF response signals in response to reception of the at least one RF interrogation signal. The management module is configured to process signals generated by the RF transceiver to track locations of the user-wearable unit and identify an inventory bin based on proximity of the user-wearable unit to the identified inventory bin to monitor performance of an inventory system task.