A method for dynamically associating an ultra wide band (UWB) tag with an object by an electronic device is provided. The method includes monitoring, by the electronic device, a first object and a second object in vicinity of the UWB tag over a period of time and determining, by the electronic device, a parameter associated with each of the first object and the second object with respect to the UWB tag. Further, the method includes generating, by the electronic device, a correlation between the UWB tag and each of the first object and the second object based on the parameter and dynamically associating, by the electronic device, the UWB tag with one of the first object and the second object based on the correlation between the UWB tag and each of the first object and the second object.

The presently disclosed subject matter includes a system and method for fast checkout from a retail store. The system includes a portable computerized device that is configured to track items which are inserted or removed from a shopping container.

Systems and methods are described for tracking and providing status updates for delivery of a product. An example method may include obtaining a request to process an order for transporting a product between a shipper and a receiver storage location. Shipper and receiver profiles may be identified by accessing a database comprising a plurality of tenant profiles, each profile including specifications associated with handling of the product. A set of instructions for processing the order may be determined from data associated with at least one of the shipper or receiver profiles, and communicated to a carrier device. Status updated may be generated based on data uploaded to the system via the carrier device, where the status updates may be associated with the shipper profile, the receiver profile, or both. A confirmation of the delivery may be generated based on the data obtained from the carrier device.

A computing system for alternate path generation is disclosed. In aspects, the computing system can implement methods to generate the alternate paths by: identifying an optimal path to a destination node on a first graph, generating a path graph, and generating an alternate path sequence based on the path graph. In aspects, the computing system can further generate an interactive graphical user interface (GUI) for displaying the alternate path sequence and transmit the interactive GUI to a display unit for display.

A computer-implemented method for combined indoor and outdoor tracking using a tracking device is disclosed. In at least one embodiment of the method, a fingerprint of radio signals is generated by the device at a location to be determined. The location of the device is determined by applying trained functions to the fingerprint wherein the trained functions have been end-to-end trained using a plurality of fingerprints generated at known locations. Environmental sensor data may be used to predict a lifetime of a component tracked by the tracking device.

An online shopping concierge system identifies a set of delivery orders and a set of delivery agents associated with a location. The system allocates the orders among the agents, each agent being allocated at least one order. The system obtains agent progress data describing travel progress of the agents to the location, and order preparation progress data describing progress of preparing the orders for delivery. The system periodically updates the allocation of the orders among the agents based on the agent progress data and the order preparation progress data. This involves re-allocating at least one order to a different delivery agent. When a first agent arrives at the location, the system assigns to the first agent the orders allocated to the first agent. The system then removes the first agent from the set of available delivery agents, and removes the assigned delivery orders from the set of delivery orders.

An online shopping concierge system identifies a set of delivery orders and a set of delivery agents associated with a location. The system allocates the orders among the agents, each agent being allocated at least one order. The system obtains agent progress data describing travel progress of the agents to the location, and order preparation progress data describing progress of preparing the orders for delivery. The system periodically updates the allocation of the orders among the agents based on the agent progress data and the order preparation progress data. This involves re-allocating at least one order to a different delivery agent. When a first agent arrives at the location, the system assigns to the first agent the orders allocated to the first agent. The system then removes the first agent from the set of available delivery agents, and removes the assigned delivery orders from the set of delivery orders.

An electronic notification apparatus is disclosed. The electronic notification apparatus may include an image capture device which can scan a machine readable code on a physical object. A communication may thereafter be initiated to complete the transfer of the physical object to a user.

An electronic notification apparatus is disclosed. The electronic notification apparatus may include an image capture device which can scan a machine readable code on a physical object. A communication may thereafter be initiated to complete the transfer of the physical object to a user.

A mobile robot is configured to navigate on a sidewalk and deliver a delivery to a predetermined location. The robot has a body and an enclosed space within the body for storing the delivery during transit. At least two cameras are mounted on the robot body and are adapted to take visual images of an operating area. A processing component is adapted to extract straight lines from the visual images taken by the cameras and generate map data based at least partially on the images. A communication component is adapted to send and receive image and/or map data. A mapping system includes at least two such mobile robots, with the communication component of each robot adapted to send and receive image data and/or map data to the other robot. A method involves operating such a mobile robot in an area of interest in which deliveries are to be made.