An order fulfillment system and method of fulfilling orders, each with at least one article, includes at least one mobile robotic unit that is capable of autonomous routing in an order fulfillment facility. A stationary robotic order-picking station with a stationary robot and vision equipment sorts articles into orders. The at least one mobile robotic unit transfers articles to or from the stationary robotic order-picking station.

A robotic system is disclosed that include an articulated arm and a first perception system for inspecting an object, as well as a plurality of additional perception systems, each of which is arranged to be directed toward a common area in which an object may be positioned by the robotic arm such that a plurality of views within the common area may be obtained by the plurality of additional perception systems.

A sorting control method for a three-dimensional sorting robot, a three-dimensional sorting robot and a related device are provided. The method comprises: a state acquisition step, involving acquiring the state of a target goods basket unit of the current sorting shelf; a delivery step, involving controlling, when it is confirmed that the target goods basket unit is available, an unloading mechanism of a three-dimensional sorting robot to execute a first delivery action; a determination step, involving determining whether goods to be delivered enter the target goods basket unit, and when a delivery failure occurs, controlling the unloading mechanism of the three-dimensional sorting robot to execute a second delivery action; and a confirmation step, involving executing the determination step once or multiple times, until it is confirmed that the goods to be delivered are delivered into the target goods basket unit.

This application describes fabric storage totes, as well as techniques for use of fabric totes in an infrastructure that uses mechanical systems to transport the fabric totes and/or access inventory items in the fabric totes. The fabric totes may include a fabric base and side walls, with a hardened material support structure. Additionally, the fabric totes may include two handles made of a substantially hard material. The fabric totes may be accessed and transported, manually and/or mechanically, via interaction with the handles.

A drop perception system is disclosed that includes an open housing structure having an internal volume, an open top and an open bottom, and a plurality of perception units positioned to capture perception data within the internal volume at a plurality of locations between the open top and the open bottom of the open housing.

This application describes fabric storage totes, as well as techniques for use of fabric totes in an infrastructure that uses mechanical systems to transport the fabric totes and/or access inventory items in the fabric totes. The fabric totes may include a fabric base and side walls, with a hardened material support structure. Additionally, the fabric totes may include two handles made of a substantially hard material. The fabric totes may be accessed and transported, manually and/or mechanically, via interaction with the handles.

Provided is a technique of transporting an object to be transported to a machine tool more securely. A transport system includes a transport path, and a storage portion. The storage portion stores an object, and has a first reference shape. The transport system includes machine tools, and a transport device that moves on and the transport path and transports an object. The control unit executes a process of making a camera photograph the first reference shape to acquire a first image from the camera, and a process of correcting a control parameter to be used in transporting an object to be transported stored in the storage portion to the machine tool that is a transport destination on the basis of a position of the first reference shape in the first image.

A sortation system is disclosed for providing processing of homogenous and non-homogenous objects in both structured and cluttered environments. The sortation system includes a programmable motion device including an end effector, a perception system for recognizing any of the identity, location, and orientation of an object presented in a plurality of objects, a grasp selection system for selecting a grasp location on the object, the grasp location being chosen to provide a secure grasp of the object by the end effector to permit the object to be moved from the plurality of objects to one of a plurality of destination locations, and a motion planning system for providing a motion path for the transport of the object when grasped by the end effector from the plurality of objects to the one of the plurality of destination locations, wherein the motion path is chosen to provide a path from the plurality of objects to the one of the plurality of destination locations.

A robotic system is disclosed that include an articulated arm and a first perception system for inspecting an object, as well as a plurality of additional perception systems, each of which is arranged to be directed toward a common area in which an object may be positioned by the robotic arm such that a plurality of views within the common area may be obtained by the plurality of additional perception systems.

A robotic logistics system is disclosed. The system includes multiple robots each having an image capture unit and a server communicatively coupled to the multiple robots. The server is configured to transmit a location of a first item to a first robot and the location of a second item to a second robot; track the positions of the first robot and the second robot; transmit a first image of the first item captured by the first robot to an operator device; receive a first verification signal from the operator device in response to the first image; transmit a second image of the second item captured by the second robot to the operator device; and receive a second verification signal from the operator device in response to the second image.