Embodiments generally relate to systems, methods, and processes that may use touch-free document reading at self-service interaction stations. Some embodiments relate to a self service station for conducting a passenger interaction process in transit environment, including, a display screen to display a visual prompt to present a travel document in a field of view of a video image recording device as part of the passenger interaction process, and configured to determine from the received live video images a document face image present on the travel document, to determine from the received live video images a machine-readable zone (MRZ) of the travel document and store a captured MRZ image of the MRZ, to process the captured MRZ image to determine identification information on the travel document, and store the document face image and the identification information for use in the passenger interaction process.

Embodiments generally relate to systems, methods, and processes that may use touch-free document reading at self-service interaction stations. Some embodiments relate to a self service station for conducting a passenger interaction process in transit environment, including, a display screen to display a visual prompt to present a travel document in a field of view of a video image recording device as part of the passenger interaction process, and configured to determine from the received live video images a document face image present on the travel document, to determine from the received live video images a machine-readable zone (MRZ) of the travel document and store a captured MRZ image of the MRZ, to process the captured MRZ image to determine identification information on the travel document, and store the document face image and the identification information for use in the passenger interaction process.

A base station configured for charging an autonomous drone may comprise a first conductive groove and a second conductive groove. The first conductive groove and the second conductive groove may be configured to interface with a first conductive strip and a second conductive strip disposed on a landing gear of the autonomous drone. The base station may be configured to charge a battery of the autonomous drone in response to the first conductive groove interfacing with the first conductive strip and the second conductive groove interfacing with the second conductive strip.

A distribution device (10) is provided with an acquisition unit (11) which acquires position information of an obstacle, and a distribution unit (12) which wirelessly distributes, from the obstacle to an aircraft, obstacle information including the acquired position information of the obstacle and identification information of the obstacle. The distribution device (10) distributes the identification information of the obstacle along with the position information of the obstacle to the aircraft, and the aircraft interprets the position, etc., of the specific obstacle.

A transportation system and method serve passenger-conveying VTOL air vehicles (AVs) at a vertiport. The vertiport has a flight deck including at least one landing pad, a passenger terminal, and a dynamic partition arrangement that defines a capsule for receiving one of the AVs at a time. The dynamic partition arrangement assumes a first open state in which it is open to the flight deck and closed to the passenger terminal and a second open state in which it is closed to the flight deck and open to the passenger terminal. A robotic system includes a handling robot that automatically approaches and docks with the AV after landing, and conveys the AV between the landing pad and the capsule via an opening provided by the first open state of the dynamic partition.

A determination device according to one embodiment includes an acquiring unit (231) and a determination unit (233). The acquiring unit (231) acquires positional information that is related to a terminal device installed at an arbitrary location serving as a reference for a path of an air vehicle and that is calculated on the basis of correction information that includes information on coordinates of a reference station associated with an area in which the terminal device is positioned and information based on a satellite signal received by the reference station. The determination unit (233) determines a flight path of the air vehicle on the basis of the positional information acquired by the acquiring unit.

This specification describes an electrically powered modular platform comprising a power module comprising a common power bus, the power module electrically connected to a power source; one or more service modules that provide a service; a termination module that is configured to cover an opening in the one or more service modules, wherein the power module, each of the one or more service modules, and the termination module are modular and stackable, and wherein the power module and each of the one or more service modules are electrically connected using the common power bus to provide power to each of the one or more service modules.

An information processing device includes an association information acquiring unit, a first position information acquiring unit, and an output control unit. The association information acquiring unit acquires association information in which first identification information used for identifying baggage and second identification information used for identifying an owner of baggage identified by the first identification information are associated with each other. The first position information acquiring unit acquires position information of target baggage that is baggage identified by the first identification information included in the association information. The output control unit causes a mobile terminal held by a target owner who is an owner of the baggage identified by the second identification information associated with the first identification information relating to the target baggage in the association information to output information based on the position information of the target baggage.

A system for charging an electric aircraft including a horizontal cable arrangement, including a charger base including an energy source and a charging cable electrically connected to the energy source. The system further including a horizontal cable including at least a length of the charging cable and having a first cable arrangement position, wherein the horizontal cable arrangement is located at a first elevation, and a second cable arrangement position, wherein the horizontal cable arrangement is located at a second elevation. The second elevation is greater than the first elevation. The system further including a lift in contact with the horizontal cable arrangement. The lift having a first lift position and a second lift position. In the first lift position, the horizontal cable arrangement is in the first cable arrangement position, and in the second lift position, the horizontal cable arrangement is in the second cable arrangement position.

The platform comprises supporting legs (12) fastened to the platform (10), and a control unit (13) and provides an electrical charging system including a plurality of coplanar adjacent electroconductive plates (14), with adjacent edges electrically insulated, arranged on an electrically insulated support. Each electroconductive plate (14) is connected by an electroconductive cable (15) to the control unit (13) and to a power source (16), wherein the electroconductive plate (14), electroconductive cable (15) and control unit (13) form an electrical circuit and the control unit (13) is configured to detect a change of an electric potential and/or current of the electrical circuit due to a UAV, landing on said platform and providing at least two points of contact with two different electroconductive plates (14). The platform supply energy, from power source to said two different electroconductive plates (14) using corresponding electroconductive cables (15) in order to charge powering means of said UAV.