A vehicular information processing apparatus includes a storage unit in which running states of a vehicle each including a height of the vehicle and a manner of drive power distribution are stored so as to correspond to respective running modes, an input/output device that receives an input manipulation for selecting one of the running modes and a display control unit that causes the input/output device to make a display that indicates the selected running mode. The display control unit causes the input/output device to display a running state corresponding to the selected running mode in the form of an animation together with a skeleton image of the vehicle, and then display an appearance of the vehicle.

Disclosed are a drunk driving prevention system and a method of controlling the system that includes a sensor module measuring a alcohol content in the exhaled breath of a driver during a breath-checking of the driver and a control module configured to check the intoxication state of the driver from the alcohol content measured by the sensor module to determine whether the breath-checking is complete and block an engine start when the breath-checking fails, wherein the control module includes a check unit displaying breath-checking guide information through a display unit and the check unit displays the breath-checking guide information based on an engine start input of the driver.

A computer performs processing including: generating an image to be presented to a driver in a preset coordinate system; identifying a display position at which the generated image is displayed in a field of vision of a driver, based on a viewpoint position of the driver; generating a driver viewpoint image obtained by converting the generated image to an image represented in a coordinate system defined with the viewpoint position as a reference; causing the driver viewpoint image to be displayed in such a manner that the driver viewpoint image overlaps a field of vision of the driver; detecting a line of sight of the driver; and when determining that a change amount of the detected line of sight exceeds a threshold value, suppressing change in a position at which the driver viewpoint image is displayed occurring in association with change in the viewpoint position.

A computing system associated with a vehicle can access sensor data originating from one or more sensors disposed within a vehicle and can access device data originating from a user device. The sensor data and the device data can comprise physiological data of a user of the vehicle. The computing system can determine a physiological status of the user of the vehicle based on at least the sensor data or the device data and cause the vehicle to perform one or more operations based on at least the physiological status of the user.

The present invention relates to an apparatus and method for controlling a vehicle using rotation information of a mobile terminal. The apparatus for controlling a vehicle using rotation information of a mobile terminal includes an input unit configured to receive rotation information of a mobile terminal, a memory configured to store a program for controlling a vehicle based on the rotation information, and a processor configured to execute the program, wherein the processor recognizes a view mode of the mobile terminal from the rotation information and provides a vehicle control screen according to the view mode.

A vehicular display apparatus is provided. The vehicular display apparatus includes a driving device installed in a housing, a display module configured to move to an inner portion or an outer portion of the housing, based on a mechanical operation of the driving device, and a controller unit configured to control the mechanical operation of the driving device. The driving device includes a gear configured to move the display module to the inner portion or the outer portion of the housing and a light emitting sensor and a light receiving sensor facing each other with the gear therebetween. The light receiving sensor senses an optical signal of the light emitting sensor passing through a region between gear teeth of the gear, and the controller unit counts the number of gear teeth of the gear passing through a region between the light emitting sensor and the light receiving sensor on a basis of a sensing result of the light receiving sensor and controls movement of the display module, based on the counted number of gear teeth.

A system includes a display and a processor coupled to the display. The processor determines a position of a vehicle relative to a road lane and causes the display to depict a set of position indicators to convey the position of the vehicle relative to the road lane. In one state, the set of position indicators include a plurality of empty shape outlines and at least one filled shape outline. The processor also determines a position of a hazard relative to the vehicle and causes the display to depict a set of hazard position indicators to convey the position of the hazard relative to the vehicle. In one state, the set of hazard position indicators include a plurality of empty shape outlines and at least one filled shape outline.

According to the invention, a method for modifying operation of at least one system of a vehicle based at least in part on a gaze direction of a driver is disclosed. The method may include receiving gaze data indicative of the gaze direction of a driver of a vehicle. The method may also include modifying operation of at least one system of the vehicle based at least in part on the gaze data.

An automatic adjuster, when carrying out an AR superimposed display using a head-up display in a vehicle like a car, is able to perform eye position adjustment for the AR superimposition automatically without increasing a burden to a driver by controlling, according to the eye position information acquired from an eye position detector, in such a manner as to shift the driver's eye position in accordance with the reference position of the superimposed display, which serves as a position where the AR superimposition is performed appropriately, and by controlling a movable part of the driver's power seat the driver of the vehicle takes.

A control system for a vehicle for transferring data from a communication device, which may include at least one control interface configured to receive a first input from a driver and a display configured to generate an output visible to the driver. The control system may also include a controller in communication with the communication device, the at least one control interface, and the display. The controller may be configured to receive data from the communication device and generate and output a query to the display based on the data. The controller may also be configured to receive the first input from at least one control interface and output the data to the display based on the first input.