A collision avoidance and/or pedestrian detection system for a large passenger vehicle such as commuter bus, which includes one or more exterior and/or interior sensing devices positioned strategically around the exterior and interior of the vehicle for recording data, method for avoiding collisions and/or detecting pedestrians, and features/articles of manufacture for improving same, is described herein in various embodiments. The sensing devices may be responsive to one or more situational sensors, and may be connected to one or more interior and/or exterior warning systems configured to alert a driver inside the vehicle and/or a pedestrian outside the vehicle that a collision may be possible and/or imminent based on a path of the vehicle and/or a position of the pedestrian as detected by one or more sensing devices and/or situational sensors.

Often when there is a glare on a display screen the user may be able to mitigate the glare by tilting or otherwise moving the screen or changing their viewing position. However, when driving a car there are limited options for overcoming glares on the dashboard, especially when you are driving for a long distance in the same direction. Embodiments are directed to eliminating such glare. Other embodiments are related to mixed reality (MR) and filling in occluded areas.

A system for displaying vehicle driving information may include: first and second image acquisition devices configured to capture an image of a first side on which a driver seat is located and an image of a second side which is the opposite side of the first side, respectively; first and second display devices configured to display the captured images of the first and second image acquisition devices, respectively; first and second BSD devices and configured to sense side-rear vehicle information; and a control device configured to recognize the location and vehicle distance of the side-rear vehicle by analyzing the side-rear vehicle information detected by the first and second BSD devices, determine whether to issue a BSD warning, and control BSD warning icons of the ego vehicle and the side-rear vehicle to be displayed as an OSD of the images displayed on the first and second display devices.

An automatic parking control unit comprises a recognizing section recognizing an outer world outside a vehicle, a vehicle operation control section performing an operation control on the vehicle, an automatic parking control section performing a parking operation to park the vehicle at a target parking position and a display control section synthesizing images taken by a camera group into an image of a surrounding area of the vehicle and displaying the image on an output device group. The display control section displays an image of the surrounding area of the vehicle and a vehicle body image of the vehicle with a portion of the vehicle made translucent, the portion of the vehicle making a blind area to a driver in the surrounding area of the vehicle and the portion of the vehicle is changed according to a direction in which the vehicle is running.

A method for enhancing situational awareness in a transportation vehicle including combination tractor and a trailer. The method includes locating a plurality of cameras on the trailer of the vehicle. Each camera is equipped with a camera wash system including a wash nozzle, dryer, and defroster. The cameras are operatively connected to a local area user network via an onboard access point. The onboard access point communicates with a data bus of the vehicle. At vehicle start-up, the cameras are automatically paired with a computing device located inside the tractor. The computing device includes a display screen and graphical interface with icon tabs representing each of the connected cameras. Using the icon tabs rendered on the display screen of the computing device, a selected camera and associated camera wash system can be manually activated.

A virtual visor system is disclosed that includes a visor having a plurality of independently operable pixels that are selectively operated with a variable opacity. A camera captures images of the face of a driver or other passenger and, based on the captured images, a controller operates the visor to automatically and selectively darken a limited portion thereof to block the sun or other illumination source from striking the eyes of the driver, while leaving the remainder of the visor transparent. The virtual visor system advantageously detects whether the driver of other passenger is performing particular head gestures and updates the optical state of the visor using suitable modified procedures that accommodate the intent or goals of the driver or other passenger that are inferred from the predefined head gesture. In general, the modified procedures reduce distracting or frustrating updates to the optical state of the visor.

A blind spot warning method is disclosed for a tow vehicle. The method includes determining whether a trailer is connected to the tow vehicle. Based on the determination whether the trailer is connected to the tow vehicle, the determines whether a blind spot zone corresponds to the tow vehicle or to the tow vehicle and the trailer. At least one instruction is sent to a user interface of the tow vehicle for displaying an image for viewing by a driver of the tow vehicle. The displayed image indicates the determination whether the blind spot zone corresponds to the tow vehicle or to the tow vehicle and the trailer, and indicates a presence or absence of at least one other vehicle disposed in the blind spot zone.

An augmented reality system may include a data gathering device configured to collect data regarding an environment exterior to the vehicle. In addition, the system may include a vehicle controller including a device processor and a non-transitory computer readable medium including instructions, executable by the processor, for performing the following steps: receiving data from the data gathering device; and transmitting information to a set of augmented reality goggles in order to facilitate a projection of a modified view of an interior of the vehicle based on the data collected regarding the environment exterior to the vehicle.

A control system for construction machinery includes an upper camera installed in a driver cabin to photograph the front of the driver cabin, a lower camera installed in a vehicle body to photograph the front of the vehicle body, a work apparatus posture detection portion configured to detect a posture of the work apparatus connected rotatably to the vehicle body, an image processing portion configured to synthesize first and second images captured from the upper camera and the lower camera into one image, and configured to transparency-process at least one of the first and second images in the synthesized image according to the posture of the work apparatus detected by the work apparatus posture detection portion, and a display device configured to display the synthesized image transparency-processed by the image processing portion.

A method of assisting a driver of a vehicle with visualization of an ambient environment comprises generating a mirror image signal corresponding to a field of view of a traditional driving mirror. A surround image signal corresponding to a field of view of an ambient environment adjacent the vehicle is generated. A vehicle speed signal is generated. The mirror image signal, the surround image signal, and the vehicle speed signal are received, and at least one of a driver mirror signal and a driver surround signal is responsively produced. A video image corresponding to at least one of the driver mirror signal and the driver surround signal is selectively displayed to the driver. A frame rate of at least one of the mirror image signal and the surround image signal is adjusted by the signal processor responsive to the vehicle speed signal. A drive assist system is also provided.