A system is described herein. The system includes a merchant server hosting a marketplace service and a computing device. The marketplace service is configured to access a first website housing products and a second website housing products, perform an acquisition operation to extract information about a first product of the products from the first website and from the second website, and aggregate the information about the first product into a comparison format. A marketplace application of the computing device allows the user to access the marketplace service. The marketplace application transmits a request received from the user for the information associated with the first product to the marketplace service, where the marketplace service executes the request and displays the comparison format of the information for the first product to the user via a graphical user interface (GUI) of the computing device.

A processing system for processing objects is disclosed that includes a plurality of receiving stations for receiving a plurality of objects, each object being associated with prerecorded data, and a plurality of processing stations, each of which is in communication with at least one processing station. Each processing station includes perception means for perceiving data regarding an identity of any of an object or a bin of objects, and capture means for capturing characteristic data regarding an object to provide captured data. Each processing station further includes comparison means for comparing the captured data with the prerecorded data to provide comparison data, and a plurality of distribution stations, each of which is in communication with at least one processing station for receiving objects from the at least one processing station responsive to the comparison data.

Methods and systems are described for optimizing delivery modes used to transport items to a customer. A delivery optimization system includes an online ordering system, a delivery mode optimizer, an order allocator, a cartonization engine, and a ship label and manifest generator. The delivery mode optimizer selects an optimal shipping mode based on information received from carriers. The lowest cost option to deliver the goods to the destination by a promised delivery date is selected at the time the order is received. A shipping node is selected that can supply the items needed to fulfill the order within the desired timeframe. Cartons are selected to package the items in the order in the most cost effective manner. The delivery mode is reevaluated after the order is prepared for shipment to determine if available shipping options have changed.

Systems, methods, and media of terminal site optimization are provided. A method includes receiving input specifying a current terminal. The method also includes receiving input specifying one or more potential terminal relocation sites. The method further includes analyzing costs of a relocation site based upon shipping costs on a per-service area basis. The costs of a relocation site are also analyzed based upon pickup costing and delivery costing on a per-service area basis. The costs of a relocation site are additionally analyzed based upon adjusted costs for the current terminal. The method additionally includes outputting current and change-site costing data.

The present disclosure provides a computerized method item correlation including: receiving an indication of an order comprising at least one item; determining if the order is urgent based on an amount of time remaining until the items must ship to a customer; determining a location of each of a plurality of pickers; iteratively, for items in the order: identifying a picker closest to the item, the picker having a current job priority; correlating the closest picker and the item in a data structure; re-correlating, in the data structure, at least one item previously correlated with the closest picker to an alternate picker in response to the current job priority not being urgent; sending, to a user device of the closest picker, a location and item identifier associated with the item; and storing, in the data structure, a completion flag in correlation with the item upon receipt of an item-complete message.

A method for recipient-initiated shipping includes receiving, at an internet connected server, recipient data (including a first shipping address) from a shipping recipient; providing delivery options to the shipping recipient based on a set of delivery option criteria and the recipient data; receiving a delivery choice from the shipping recipient; and notifying at least one of a shipping sender and a shipping carrier of the delivery choice.

A vehicle dispatch device includes a position determination unit determining whether or not a destination and a delivery place match each other, a calculation unit calculates a delivery service fee to the delivery place, and a distance determination unit determining whether or not a boarding distance from a boarding position to the destination is equal to or longer than a reference boarding distance, wherein when the destination and the delivery place do not match each other and the boarding distance is not equal to or longer than the reference boarding distance, the calculation unit calculates a first delivery service fee, and when the destination and the delivery place do not match each other and the boarding distance is equal to or longer than the reference boarding distance, the calculation unit calculates a second delivery service fee, which is lower than the first delivery service fee.

Aspects include a system, method and computer program product for delivering a package via an unmanned aerial vehicle (UAV). A delivery parameter for delivering the package via the UAV is obtained. A weather parameter related to the delivery parameter is obtained. A flight configured for the UAV is selected, wherein the selected flight configuration reduces a delivery cost of the package via the UAV based on the weather parameter and the delivery parameter. The package is delivered using the selected flight configuration of the UAV.

Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, for a logistics planner are disclosed. In one aspect, a method includes the actions of receiving data indicating orders for materials to be delivered to first locations and data indicating amounts of the materials stored at second locations. The actions further include providing the data indicating the orders for the materials to be delivered to the first locations and the data indicating the amounts of the materials stored at the second locations as inputs to models. The actions further include generating a graph that includes first nodes and second nodes. The actions further include generating a sub-graph. The actions further include determining an amount of each material to be delivered. The actions further include determining a route to travel and an amount of each material to transport.

A computer-implemented method is disclosed. The method includes: receiving input of product value data for a product item and a data modifier for the product value data, the data modifier identifying a target margin value associated with the product item; determining at least one current inventory location for the product item; obtaining a shipping rate associated with shipping the product item to a geographical region from the at least one current inventory location; retrieving historical transfer value preference data for the geographical region; modifying at least one of the product value data, the shipping rate, or the target margin value based on the historical transfer value preference data; determining a transfer value of the product item based on the modified at least one of the product value data, the shipping rate, or the target margin value; and generating an indication of the transfer value of the product item.