CPC Class H04N

An interior structure for a vehicle includes an instrument panel disposed below a windshield, an air conditioning duct provided inside the instrument panel, and a head-up display device having a housing structure and mounted to the instrument panel, the head-up display device being configured to project information on the windshield. The head-up display device has a heat dissipating portion on an outer peripheral face of the housing. The air conditioning duct has a facing portion that faces the heat dissipating portion so as to be able to exchange heat with the heat dissipating portion.

A system for generating a moving image in an aircraft, includes a multiplicity of LEDs, a signal input unit, into which image information is fed, a signal output unit coupled to the multiplicity of LEDs and configured for transmitting the image information to the multiplicity of LEDs, and a gyroscopic sensor for acquiring a spatial position of the aircraft, wherein the LEDs are arranged in the form of a grid on an aircraft interior wall, such that the image is a schematic reproduction of the image information and the signal output unit is coupled to the gyroscopic sensor in such a way that the position of the image is matched to the spatial position of the aircraft, such that the image forms an artificial horizon for a viewer.

A driving assistance system includes a database configured to store numbers of preset criteria concerning various driving conditions, a sensor, configured to sense environmental data surrounding a vehicle; a thermal image capturing device, configured to capture a thermal images surrounding the vehicle; a display device; and a processor, coupled to the sensor, the thermal image capturing device and the display device. The processor compares the environmental data against the preset criteria to determine the driving condition of the vehicle. The display device automatically display thermal images to inform and provide precautions to the driver if the driving condition indicates that the driver's vision is adversely affected.

An electro-optic mirror reflective element for a rearview mirror assembly for a vehicle includes a front substrate and a rear substrate with an electro-optic medium disposed therebetween. A display element is disposed at the front substrate and includes a transparent organic light emitting diode display. With the electro-optic mirror reflective element disposed at a rearview mirror assembly at the vehicle and when the display element is activated, information displayed by the display element is viewable by a driver of the vehicle. With the electro-optic mirror reflective element disposed at the rearview mirror assembly at the vehicle and when the display element is not activated, the driver views reflected images of the scene rearward of the vehicle as reflected off a specularly reflective mirror reflector disposed at a surface of the rear substrate.

An autonomous robot vehicle in accordance with aspects of the present disclosure includes a land vehicle conveyance system, a sensor system configured to capture information including surrounding environment information and/or vehicle subsystem information, a communication system configured to communicate with a remote human operator management system, at least one processor, and a memory storing instructions. The instructions, when executed by the processor(s), cause the autonomous robot land vehicle to, autonomously, determine based on the captured information to request a remote human operator, and communicate a request to the remote human operator management system for a remote human operator to assume control of the land vehicle conveyance system, where the request includes at least a portion of the captured information.

A system and method for simulating lead of a target includes a network, a simulation administrator and a user device connected to the network, a database connected to the simulation administrator, and a set of position trackers positioned at a simulator site. The user device includes a virtual or augmented reality unit and a computer connected to the network. A target may be simulated or may be a real-world object. The target and the user are tracked to generate a phantom target and a phantom halo. The phantom target and the phantom halo are displayed on the virtual or augmented reality unit at a lead distance and a drop distance from the target.