A vehicle includes a first sensor for sensing a first image, a second sensor for sensing a second image, and a processor that is configured to generate seating information of a passenger based on the first image, and generate posture information of the passenger with the generated seating information based on at least one of the first image or the second image.

A display system of a vehicle includes a person detection device that detects a person on one side of the vehicle in a top view of the vehicle, a display device provided on the vehicle exterior on the side opposite to the one side of the vehicle, and a controller that controls the display device. When the person detection device detects a person, the controller controls the display device to display a warning indicating presence of the person, on a display of the display device.

Disclosed is an electronic device for a vehicle, including a processor acquiring image data acquired by a camera mounted in a vehicle, determining a riding intention of an outside person based on the location, posture, and gesture of the outside person detected from the image data, and generating a control signal to stop the vehicle based on the riding intention.

A school bus having a pedestrian lighting system includes bus entrance door lamps that illuminate an area adjacent to the entrance door of the bus. Switch logic circuitry is connected to and controls bus door entrance lamp circuitry that provides power to the bus entrance door lamps. A power cutoff noise suppression switch, which otherwise functions to turn off noise generating devices in the bus when stopping for a railroad crossing, is connected to the switch logic circuitry or to delayed deactivation timer circuitry. The power cutoff noise suppression switch and the switch logic circuitry or the delayed deactivation timer circuitry are configured so that input of the switch logic circuitry to the bus door entrance lamp circuitry is overridden, and the at least one bus entrance door lamp is turned off, when the power cutoff noise suppression switch is activated.

An aircraft light comprises a support board; a light source, arranged on the support board; a first optical element, which is at least partially light transmissive, which is arranged over the light source, and which is fixed to the support board; and a second optical element, which is at least partially light transmissive, wherein the first optical element is interposed between the light source and the second optical element. The first optical element has a first engagement portion and the second optical element has a second engagement portion. The first engagement portion and the second engagement portion establish a positive fit between the first optical element and the second optical element. At least a portion of light, which is emitted by the light source in operation, passes through the first optical element and through the second optical element.

Disclosed is an electronic device for a vehicle, including a processor acquiring image data acquired by a camera mounted in a vehicle, determining a riding intention of an outside person based on the location, posture, and gesture of the outside person detected from the image data, and generating a control signal to stop the vehicle based on the riding intention.

A display system of a vehicle includes a person detection device that detects a person on one side of the vehicle in a top view of the vehicle, a display device provided on the vehicle exterior on the side opposite to the one side of the vehicle, and a controller that controls the display device. When the person detection device detects a person, the controller controls the display device to display a warning indicating presence of the person, on a display of the display device.

Automated control of one or more exterior aircraft lights is presented, for instance exterior aircraft lights that enhance visibility by a pilot and including landing lights, taxi lights, and runway turnoff lights. One aspect of this automated control is that one or more of such exterior aircraft lights may be automatically activated, for instance when the aircraft has at least initiated movement and has not yet reached a certain altitude (e.g., while the aircraft is taxiing on the ground and including during takeoff). Another aspect of this automated control is that a trained image classification model may determine a visibility classification for an image acquired by an exterior aircraft camera, and this visibility classification may be used to automatically control the operation of one of more of such exterior aircraft lights (e.g., an intensity of the light output from such an exterior aircraft light(s)).

In one instance, a light weight safety arm is coupled to and extends beyond a stop sign coupled to a motor-driven rotatable mount on an exterior side of a school bus. In another instance, a school bus safety device is disclosed that includes a stop sign portion, an arm portion, and a mounting portion. The arm portion, stop sign portion and mounting portion are cut out together as one piece from a single sheet of material. Other embodiments and variations are further disclosed.

Automated control of one or more exterior aircraft lights is presented, for instance exterior aircraft lights that enhance visibility by a pilot and including landing lights, taxi lights, and runway turnoff lights. One aspect of this automated control is that one or more of such exterior aircraft lights may be automatically activated, for instance when the aircraft has at least initiated movement and has not yet reached a certain altitude (e.g., while the aircraft is taxiing on the ground and including during takeoff). Another aspect of this automated control is that a trained image classification model may determine a visibility classification for an image acquired by an exterior aircraft camera, and this visibility classification may be used to automatically control the operation of one of more of such exterior aircraft lights (e.g., an intensity of the light output from such an exterior aircraft light(s)).