Provided is a night vision output device comprising: an optical pulse output unit for outputting pulsed light at specific periods; a photographing unit having an image sensor for forming a plurality of images by using pulsed light reflected by an external object; a display unit for outputting a final image formed by synthesizing the plurality of images; and a control unit for calculating distance information of an object displayed in each pixel by using data of a brightness ratio for a distance and a brightness ratio for each pixel of the final image, wherein, in one frame, the control unit controls the image sensor such that the image sensor is activated while having different delay times on the basis of an output termination time of the pulsed light.

There is provided an image processing apparatus that displays the camera captured image via the spin window on the display and the condition of the travel direction even in the bad weather can be more reliably checked. The image processing apparatus includes a camera that captures an image via the spin window, an image processor that generates a display image, and a display that displays the generated image by the image processor. The image processing apparatus further includes a pulse light output unit, and the camera includes a first camera and a second camera that capture images at timings after elapse of different times from a pulse light output timing of the pulse light output unit. The respective cameras capture images of different spaces, and the image processor generates a differential image between the images captured by the respective cameras and displays the differential image on the display. In the differential image, the obstacle present only in either one of the spaces is more clearly displayed.

A rear backup system for a vehicle includes a rear backup video camera and a display device including a video display screen operable to display video images viewable by a driver of the vehicle. When a transmission of the vehicle is shifted into reverse gear to commence a backup event, video backup images derived from image data captured by the rear backup video camera are displayed at the video display screen of the display device. Display of the video backup images continues after shifting of the transmission out of reverse gear. Display of the video backup images at the video display screen ceases once a threshold condition is met. The threshold condition may include a threshold period of time elapsing after the transmission has been shifted out of reverse gear. The rear backup video camera continues to capture image data at least until the threshold condition is met.

A vehicular dual mode illumination module includes mounting structure configured for mounting at a vehicle, a first light emitting diode (LED) operable to emit visible white light when electrically powered, and a second near-infrared (near-IR) LED operable to emit non-visible near-IR light when electrically powered. When the vehicle is parked and the first LED is electrically powered, the first LED emits visible white light to provide visible illumination at a first region exterior the vehicle. Electrical powering of the first LED is locked-out during movement of the vehicle. When the second near-IR LED is electrically powered, the second near-IR LED emits non-visible near-IR light to illuminate a second region exterior the vehicle and to provide non-visible illumination for a camera viewing the second region. Electrical powering of the second near-IR LED is not locked-out during movement of the vehicle.

A vehicular dual mode illumination module includes mounting structure configured for mounting at a vehicle, a first light emitting diode (LED) operable to emit visible white light when electrically powered, and a second near-infrared (near-IR) LED operable to emit non-visible near-IR light when electrically powered. When the vehicle is parked and the first LED is electrically powered, the first LED emits visible white light to provide visible illumination at a first region exterior the vehicle. Electrical powering of the first LED is locked-out during movement of the vehicle. When the second near-IR LED is electrically powered, the second near-IR LED emits non-visible near-IR light to illuminate a second region exterior the vehicle and to provide non-visible illumination for a camera viewing the second region. Electrical powering of the second near-IR LED is not locked-out during movement of the vehicle.

An image display device 12 includes a camera 20 for imaging a rear of a vehicle 10, a reference position detection section 80 for detecting a reference position indicating a relative position of eyes 104 of an operator 100 relative to a display part 50, and an image control section 82 for extracting a part of an imaged image of the camera 20 thereby to display it as a circumferential image on the display part 50 and changing an extraction range of the imaged image in accordance with the reference position. The image control section 82 increases or decreases a movement amount of the extraction range relative to a change amount of the reference position in comparison with the case of a normal mirror 120.

A vision system for a vehicle includes a camera disposed at the vehicle and having a field of view exterior of the vehicle. The camera includes a lens and an imager. A control includes a processor that processes image data captured by the camera. A light emitting device includes at least one light emitting diode. The light emitting device, when the at least one light emitting diode is powered, emits near infrared light at a region encompassed by the field of view of the camera. The control, responsive to processing of image data captured by the camera, determines an ambient light level exterior the vehicle. The control, responsive to the determined ambient light level, automatically controls intensity of the near infrared light emitted by the light emitting device.

An optronic vision apparatus with which a land vehicle is intended to be equipped, includes a panoramic image sensor, at least one orientable camera, having a better resolution in a field of view that is smaller than the field of view of the panoramic image sensor, and an image-displaying device; wherein it also comprises a data processor that is configured or programmed to: receive at least one first image from the panoramic image sensor and one second image from the orientable camera; from the first and second images, synthesize a composite image in which at least one section of the second image is embedded in a section of the first image; and transmit the composite image to the image-displaying device. An armored vehicle equipped with such an optronic vision apparatus. A method by such an optronic apparatus is provided.

Eye Blind Side Driving System is a camera system that allows its user to see the complete blind side of any vehicle in day or night settings. Specifically targeting Commercial Combination Vehicles. It has the ability to be moved from vehicle to vehicle in various settings, i.e. hauling heavy equipment, tankers, van trailers, mobile homes, shipping containers and just everyday cars, making it universal in its applications. It is designed to help make roadways safer by allowing the driver to see. It can record real time events for investigations and training purposes.

A system mountable in a motor vehicle. The system includes a camera and a processor configured to receive image data from the camera. The camera includes a rolling shutter configured to capture the image data during a frame period and to scan and to read the image data into multiple image frames. A near infra-red illuminator may be configured to provide a near infra-red illumination cone in the field of view of the camera. The near infra-red illumination oscillates with an illumination period. A synchronization mechanism may be configured to synchronize the illumination period to the frame period of the rolling shutter. The frame period may be selected so that the synchronization mechanism provides a spatial profile of the near infra-red illumination cone which may be substantially aligned vertically to a specific region, e.g. near the center of the image frame.