Disclosed are systems, methods, and non-transitory computer-readable media for presenting an Augmented Reality (AR) visualization of an Advanced Driver Assistance System (ADAS). A viewing device integrated into a vehicle gathers sensor data from one or more sensors. The sensor data describes a speed and trajectory of the vehicle and a geographic location of a physical object in relation to the vehicle. The viewing device determines, based on the sensor data, that a threat level of the vehicle colliding with the physical object meets or exceeds a threshold threat level. In response to determining that the threat level of the vehicle colliding with the physical object meets or exceeds the threshold threat level, the viewing device determines an automated movement of the vehicle to avoid colliding with the physical object. The viewing device then presents, on a heads up display of the vehicle, virtual content depicting the automated movement, and executes the automated movement.

A glare detection apparatus for detection of at least one glare region within an image includes a processing unit configured to aggregate image pixels of the image having a high luminance intensity to bright image areas within the image and to calculate for image pixels around each bright image area gradients expected in case of a glare and actual gradients and configured to increase a glare diameter of a glare region around the respective bright image area as long as the calculated actual gradients match the calculated expected gradients.

Disclosed is a display apparatus for vehicle comprising: a display unit; an interface unit; and a processor configured to receive information on a first object and a second object positioned outside a vehicle through the interface unit, and control the display unit to display a graphic object corresponding to the first object, when the second object is positioned between the vehicle and the first object.

In one embodiment, a safety system for playing vehicle monitored content in a vehicle while minimizing driver distraction is provided. When the driver selects a camera, such as a rear view camera, vehicle monitored content stream from the camera is displayed on a display in the vehicle. While the driver drives the vehicle, the eye-gaze of the driver is monitored. When the eye-gaze of the driver shows that the driver is looking at the display, a timer is started. The timer runs when the driver looks at the display. When the eye-gaze of the driver shows that the driver has looked at the road continuously for more than a threshold amount of time, the time associated with the vehicle monitored content is reset back to its initial value. If the timer runs out, indicating that the driver has been watching the vehicle monitored content too much without also looking at the road, the vehicle monitored content is stopped and the driver is prevented from watching the vehicle monitored content for some period of time.

A display device is configured to show an image inside a vehicle, and mounted inside the vehicle as an internal component. The display device has a light source configured to emit light, and a light guide element configured to guide incident light from the light source. The light guide element includes an emission surface configured to output incident light, and a plurality of light focusing portions configured to change the path of the incident light toward the emission surface, causing the light output to converge toward a convergence point or convergence line outside the light guide element or to radiate from a convergence point or convergence line outside the light guide element and thereby form an image outside the light guide element.

A driving support method for a vehicle includes: acquiring a sound of a sound source placed outside the vehicle; and displaying, on a display portion, driving support information corresponding to an utterance content of the sound, the utterance content of the sound being recognized by a sound recognition process, in a display mode suggesting a relative position of the sound source from the vehicle, the relative position being specified based on the sound.

The invention relates to a method for reducing the start-up time of a driver information system in a vehicle comprising providing a driver information system having an operating mode, a standby mode, and a hibernation mode. The driver information system is operated with operating power in the operating mode, is not supplied with operating power in the hibernation mode, and is operated with reduced operating power in the standby mode. A seat occupancy detection device is provided for detecting seat occupancy of at least one vehicle seat. An activation system is provided for activating and operating the driver information system in the operating mode at least when the activation system is active; and changing the driver information system from the operating mode to the standby mode when the activation system is switched off and when seat occupancy is detected at the same time.

A filter element status analysis and notification system which includes a primary control unit, a filter element which filters cabin air of a vehicle and a sensor module provided on the filter element. The sensor module including a plurality of sensors, which sensors include at least a temperature sensor and a humidity sensor. The control system being operable to detect various filter element parameters and determine potential for microbial growth. The system then providing an alert to the user regarding the determined microbial growth potential.

This disclosure relates to a method for assisting a user of a motor vehicle when swerving around an obstacle on a movement path of the motor vehicle. A driver assistance device carries out the following: providing a warning signal which describes an object on the movement path and a collision area which is visible through a window, preferably a vehicle window of the motor vehicle and in which the object is located; defining a swerving area visible through the vehicle window, in which a swerving point for travelling around the object is visible, generating an accentuation signal, which describes a measure for accentuating the swerving area, and transmitting the accentuation signal to an accentuation device. Depending on the accentuation signal, the measure for accentuating the swerving area is carried out. The accentuation device can, for example, control a heads-up display and/or a monitor integrated into the vehicle window and/or a headlight.

Estimating a lane change intention of a vehicle includes capturing a plurality of different lane change indicator signals, transforming the respective lane change indicator signals into respective associated individual probabilities of a lane change using respective assigned transformation functions, weighting these individual probabilities of a lane change, determining a weighted overall probability of a lane change as the average of the weighted individual probabilities of a lane change, and estimating the existence of a lane change intention depending on the overall probability of a lane change, and outputting an associated lane change estimation signal.