Provided is a management system for managing storage and retrieval of items. The management system includes a transfer robot that includes a drive mechanism and a sensor, the drive mechanism being configured to move a shelf along a transfer route to a region where any one of operations of carrying in an item, carrying out the item, and transferring the item between shelves is enabled to be performed, and place the shelf at a predetermined position, the sensor being configured to detect a position of the transfer robot in a space where the transfer robot is allowed to be moved, a device configured to perform at least either the operation or assistance in the operation, and a first controller configured to generate control data for controlling the device and output the control data to the device, the control data being generated on the basis of an error between a position of the shelf transferred by the transfer robot and a target position on the transfer route, the error being calculated by using the position of the transfer robot detected by the sensor.

Systems and methods are provided herein for coordinating movement of components of a workspace utilizing a controller device. The controller device may operate in a first state. The computing device may be associated with an interaction area having a first access point and a second access point, wherein a light curtain is generated at the first access point. While operating in the first state, access to the interaction area is restricted. The computing device may transition to operating in a second state based at least in part on detecting the first breach, wherein operating in the second state comprises enabling access to the interaction area at the second access point. While operating in the second state, a second breach of the light curtain may be detected and at least one remedial action performed based on the detection.

Systems and methods are described for autonomously recovering a machine comprising one or more modules. An error message from the machine is received and, based on the error message, a first module of the one or more modules to replace is determined, wherein the first module has a first type. An autonomous vehicle is instructed to remove, from the machine, the first module. The autonomous vehicle is instructed to install, at the machine, a second module of the first type.

An automation server accesses a task for a robotic device. The automation server generates motor control commands for the robotic device to complete the task. The automation server transmits, via a network and in a format defined by an Application Program Interface (API), the motor control commands from the automation server to a fleet manager associated with the robotic device, the motor control commands for forwarding from the fleet manager to the robotic device. The automation server receives, from one or more sensors attached to the robotic device and via the network, robotic device sensor data. The automation server receives, from multiple remote sensors and via the network, remote sensor data. The automation server adjusts the generated motor control commands to complete the task based on the robotic device sensor data and the remote sensor data.

A method for retrieving an inventory item based on a handling robot, where the handling robot includes: a storage frame; and a material handling device installed on the storage frame, and including a telescopic arm and a manipulator installed to the telescopic arm; and the method for retrieving an inventory item includes: driving, by the telescopic arm, the manipulator to extend to a preset position of warehouse shelf along a preset horizontal reference line; loading, by the manipulator that is remained on the reference line, the inventory item located in the preset position; driving, by the telescopic arm, the manipulator loaded with the inventory item to move to the storage frame along the reference line; and unloading, by the manipulator that is remained on the reference line, the inventory item to the storage frame.

Increased robotic sophistication and more efficient autonomous operation is implemented by providing separate physical autonomous robots shared and remote access to the sensory array and information from the sensory array of one another. Each robot can access a sensor of any other robot, or scans or other information obtained from the sensor of any other robot. The robots leverage the shared sensory access in order to perform batch order fulfillment, dynamic rearrangement of item or tote locations, and opportunistic charging. These coordinated robotic operations based on the shared sensory access increase the efficiency and productivity of the robots without adding resources or hardware to the robots, increasing the speed of the robots, or increasing the number of deployed robots.

Methods and systems are disclosed to generate and display targeted information related to a plurality of robots working in an operating environment. Plurality of nodes executing at the plurality of robots in communication with plurality of server nodes executing behaviors related to an active plan being executed on the working robots. The nodes running on the robots create Snapshots related to the executing behaviors. Information is then captured based on parent context related to the executing behaviors. The nodes populate a plurality of fields of the Snapshots with values related to at least one or more of captured information, operating environment, and the robots. The Snapshots are closed with a result of the execution of the behaviors. The Snapshots are aggregated and reported by the nodes, as part of the targeted information for display. Customized search queries or visual interfaces can be used to fix or diagnose faults or errors.

In one aspect, a warehousing apparatus comprises: a temporary storage layer board, with the temporary storage layer board being used for providing a temporary storage station; a plurality of shelves, with each shelf comprising at least one storage layer board and a plurality of stand columns arranged at intervals in the horizontal direction, the storage layer board being spaced apart from the temporary storage layer board in the vertical direction by means of the stand column, and the storage layer board being used for providing a storage position; a first robot passage for a first robot to travel in, with the first robot being used for storing goods on and taking goods to the temporary storage layer board and a second robot passage for a second robot to travel in, with the second robot being used for carrying the goods between the temporary storage layer board and the storage layer board. The warehousing apparatus along with related systems and control methods can improve the efficiency of goods entering and exiting a warehouse.

Systems and methods for autonomous provision replenishment are disclosed. Parts used in a manufacturing process are stored in an intermediate stock queue. When the parts are consumed by the manufacturing process and the number of parts in the queue falls below a threshold, a provision-replenishment signal is generated. One or more self-driving material-transport vehicles, a fleet-management system, and a provision-notification device.

System includes an article supply location that includes a plurality of articles to be sorted, first and second transport vehicles, each having a first position in which an article is stowed about the vehicle and a second position in which the article is deposited into a proximal container, and one or more removal devices that transport the container to a location of further processing. System further includes a control system configured to receive an order for a plurality of disparate articles, determine one destination container of a plurality of destination containers to direct the transport vehicle to deposit a selected article, direct the first transport vehicle to transport a selected article to the destination container, deposit the article in the destination container, and transport the destination container to a location for further processing by manipulation of the removal device.