An intelligent autonomous electrical vehicle platform assembly provides a mobile platform that comprises a self-motorized, electrical power drive to carry at least one platform container or passenger vehicle while being controlled remotely by an operator, or autonomously driven through artificial intelligence, or operated in a shared transportation system. The mobile platform has a platform chassis having wheels with a hub motor assembly contained therein. The hub motor is powered electrically from a battery charged by an external power source and/or a solar panel. The mobile platform carries a platform container that forms an enclosed area with various themes, including: a cargo transport area, a food and beverage area, a medical assistance area, or a home area having an inhabitant-assigned parking area and utility. The inhabitant of the mobile home receives creature comforts of a home environment, and controls movement, parking, energy, temperature, and payment options for the mobile home.

A delivery control system includes a communication device configured to receive an image of a product from a computing device of a customer, at least one processor, and a memory storing instructions which, when executed by the at least one processor, cause the delivery control system to perform an image recognition process on the image to identify at least one product based on the image, transmit the identified at least one product to the computing device via the communication device, receive from the computing device a product selected by the customer from among the identified at least one product, and instruct an robot vehicle to deliver the selected product to the customer.

Profits of respective stakeholders related to business by mobile shop vehicles are efficiently adjusted, and preferable schedules for the mobile shops can be created. A schedule mediation system includes: an in-vehicle server configured to hold inventory information, receive request information containing various information about merchandise etc. for which a customer asks from a user terminal, create an initial schedule for mobile sales based on a purchase place and a purchase date and time shown by purchase conditions and send it to a mediation server, receive an after-correction schedule corrected according to a mediation result in the server and, in response to this, correct the request information and sends it to the user terminal; and a schedule mediation server configured to perform mediation processing for settling a competing situation between the initial schedules shown by the mediation request, correct the initial schedule, and send an after-correction schedule to the in-vehicle server.

According to one aspect, a platform for providing at least one item to a customer is disclosed. The platform includes an autonomous, semi-autonomous, or fully autonomous vehicle that includes at least one compartment configured to contain a first item ordered by the customer and to contain a second item not ordered by the customer. The platform further includes an application including an ordering module configured to obtain an order from the customer that includes the first item, and a release detection module configured to determine when the first item has been removed from the at least one compartment and configured to determine when the second item has been removed from the at least one compartment. In one embodiment, the second item is predicted using a machine learning algorithm.

The invention discloses a mobile pellet fueled variable frequency barbecue oven as well as an electric cabinet assembly and a control circuit thereof, and relates to the field of vehicle-mounted barbecue ovens. The mobile pellet fueled variable frequency barbecue oven includes a chassis assembly, wherein the chassis assembly is connected with an automobile; a cabinet arranged above the chassis assembly, wherein the cabinet consists of a lower cabinet and a fuel tank assembly which are arranged oppositely, and is provided with a barbecue oven cavity for accommodating a food grate; and an electric cabinet assembly, wherein both sides of the electric cabinet assembly are electrically connected with the cabinet and the automobile power supply respectively to provide working power for the barbecue oven and control stable power supply of the barbecue oven. The mobile pellet fueled variable frequency barbecue oven as well as the electric cabinet assembly and the control circuit thereof replace a power supply assembly and a circuit of a traditional vehicle-mounted electric barbecue oven through a low voltage actuator, thus realizing low power operation of the vehicle-mounted barbecue oven, realizing normal work during movement of the vehicle, broadening the applicable scenarios of the vehicle-mounted barbecue oven, and being more suitable for actual use requirements.

Provided herein is an autonomous or semi-autonomous vehicle fleet comprising a plurality of autonomous or semi-autonomous vehicles for delivering a food or beverage item to a customer. The autonomous vehicle herein may comprise of storage units that are easily configured to effectively and efficiently carry different types of food or beverage items, including a temperature control system configured to maintain a target unit temperature for different types of food or beverage items.

A dynamic vending system includes a vending manager and a delivery vehicle. The vending manager is configured to receive and evaluate a plurality of dynamic conditions from the delivery vehicle and to provide instructions including a planned route to the delivery vehicle based on the dynamic conditions. The delivery vehicle includes a plurality of products available for sale, and is configured to execute the instructions including the planned route. The delivery vehicle is further configured to receive requests from consumers to stop along the planned route and to execute a transaction with the consumer for one of the products available for sale. The transaction includes the selection of one of the products available for sale, receipt of payment for the product, and dispensing the selected product to the consumer.

Connector carriers (e.g., connector carousels) for use with electronic device processing kiosks, such as mobile phone recycling kiosks, are disclosed herein. In some embodiments, a connector carrier includes a chassis and a plurality of electrical connectors fixedly positioned around a periphery of the chassis. In operation, the connector carrier is configured to rotate about a central axis to position a selected one of the electrical connectors in a first position adjacent to an inspection area of the kiosk, and then move toward the inspection area to move the selected electrical connector from the first position to a second position in which a user can connect a mobile phone to the electrical connector.

A dynamic vending system includes a vending manager and a delivery vehicle. The vending manager is configured to receive and evaluate a plurality of dynamic conditions from the delivery vehicle and to provide instructions including a planned route to the delivery vehicle based on the dynamic conditions. The delivery vehicle includes a plurality of products available for sale, and is configured to execute the instructions including the planned route. The delivery vehicle is further configured to receive requests from consumers to stop along the planned route and to execute a transaction with the consumer for one of the products available for sale. The transaction includes the selection of one of the products available for sale, receipt of payment for the product, and dispensing the selected product to the consumer.

The present invention relates to a system in a vehicle which enables fully automatic preparation of pizza during delivery in order to deliver crisp pizza fresh out of the oven to the customers. The system carries out the process starting from the fermentation of the dough up to the cooking of the product in the vehicle automatically without using manpower. Delivery with optional autonomous driving characteristic is performed without a driver. Pizza delivery vehicles operating in real time with the back office and management application, calculates the cooking time by using the position information of the vehicle and times it such that the cooking process is completed when the vehicle arrives at the delivery destination. As a result, it is enabled for the pizzas cooked inside the stone oven within the vehicle to be delivered to the customers with quality such that they were cooked in a restaurant.