An image display device includes a light source, a screen, an optical system, a converging lens, an optical distance correction member, and a scanning unit. The converging lens is configured to converge the light emitted from the light source onto the screen. The optical distance correction member is disposed between the converging lens and the screen. The scanning unit scans the screen with the light from the light source. The screen is disposed so as to be inclined with respect to a plane perpendicular to an optical axis of the converging lens so that a viewing distance of the virtual image gradually varies. The optical distance correction member adjusts an optical distance of light transmitting through the optical distance correction member so that a distance between the screen and a focusing position of the light is made substantially identical over an entire image display region in the screen.

A method for controlling a display device in a motor vehicle includes detecting a person's body posture using sensors that generate corresponding sensor values, and determining, based on the detected sensor values, whether the person is in a normotonic posture. The method also includes determining a distance between the person's eyes and the display device if the person is determined to be in a normotonic posture, and adjusting predetermined display parameters on the display device based on the distance of the person's eyes from the display device.

An image display device includes a light source, a screen, a scanning unit, an optical system, a drive unit, a support base, and a fixed base. The screen is irradiated with light from the light source, and an image is thus formed on the screen. The scanning unit scans the light from the light source along multiple scanning lines on the screen. The optical system forms a virtual image using the light from the screen. The drive unit moves the screen in an optical axis direction. The support base supports the drive unit. The fixed base supports the support base via a damper. The support base is supported by the fixed base such that the support base has support rigidity higher in a first direction in which a visual distance of a display image is changed in association with the movement of the screen than in directions other than the first direction.

An information provision device, information provision method, and a non-transitory recording medium storing a program for causing a computer to execute the information provision method. Each of the information provision device and the information provision method includes projecting an image light to a light transmission member to display a for-driver information image indicating for-driver information to be provided to a driver of a mobile object in a prescribed display area, and displaying at a first point where a normal for-driver information image is displayed a priority for-driver information image in place of the normal for-driver information image, where the displaying includes displaying the normal for-driver information image at a second point different from the first point for at least some of a period during which the priority for-driver information image is displayed at the first point.

A display generator, after activation of a display area assigned to at least one function in the interior of a vehicle, holographically displays virtual operator control elements assigned to the at least one function in the display area assigned to the at least one function in the interior of the vehicle. A detection and sensing device detects and senses gestures by a vehicle occupant which are to be interpreted as operator control inputs upon the virtual operator control elements being actuated in a manner desired by the vehicle occupant. A computing unit interprets the gestures as operator control inputs and initiates an implementation, corresponding to the operator control inputs, of the at least one function.

The present disclosure discloses a method and an apparatus for recognizing an obstacle to a vehicle. The method comprises: acquiring point cloud data of a target region by a lidar sensor and acquiring image data of the target region by using an image capturing apparatus; recognizing obstacle information in the point cloud data by a preset point cloud recognition model, and labeling a recognition result to obtain a first labeled result; recognizing obstacle information in the image data by a preset image recognition model, and labeling a recognition result to obtain a second labeled result; comparing the first labeled result with the second labeled result to decide whether the first and the second labeled result are identical; and determining a correct labeled result from the first and the second labeled result in response to the first and the second labeled result being not identical and outputting the correct labeled result.

An image display device includes a light source, a scanner, a screen, a virtual image optical system and a screen incident angle correcting optical system. The light source emits laser light. The scanner scans the laser light. An image is formed on the screen by the scanned laser light. The virtual image optical system generates a virtual image of the image by the laser light having transmitted through the screen. The screen incident angle correcting optical system orients the scanned laser light toward the screen. The scanner performs at least first scanning and second scanning that has a scanning direction different from a scanning direction of the first scanning. The screen includes a lenticular lens having a lens pitch in a direction parallel to the first scanning. The lens pitch of the lenticular lens is larger than a beam diameter of the laser light near a light receiving surface of the screen.

The present technology relates to a vehicle projection system comprising a light source configured to provide an output beam. A light splitting device is coupled to the light source to receive the output beam. Two or more optical fibers are coupled to the light splitting device to receive a split output beam from the light splitting device. Two or more projector devices are coupled to the two or more optical fibers. The two or more projector devices are configured to provide one or more display images using light received from the split output beam on one or more display surfaces in a vehicle. A vehicle including the vehicle projection system and a method of providing display images at a plurality of locations in a vehicle are also disclosed.

A main controller of an HUD is configured to: acquire road surface information of a front road surface based on a plurality of measurement points on the front road surface, which is detected by a road surface detection sensor mounted on a vehicle with the HUD and is positioned forward of a traveling direction of the vehicle; calculate, by using the road surface information, a virtual image plane position on a virtual image plane where a virtual image of a display object is displayed, which is a display position of the virtual image for displaying the virtual image along the front road surface; and calculate a display position of a display surface within an image display device, which corresponds to the virtual image plane position, so as to output, to the image display device, a control signal for displaying the display object on the display position of the display surface.

The present invention reduces distortions in a display image, and prevents decreases in visibility caused by reflected external light coming from a transmission-type screen. A head-up display device is provided with the following: a projector, for emitting display light which shows a display image; a transmission-type screen, having a light-receiving surface that receives the display light and an emission surface that emits the display light; and a second reflecting mirror that reflects the display light coming from the transmission-type screen. The transmission-type screen comprises, on one end of the emission surface, a bent section having a concave curved surface, the bent section reflecting external light, which arrives from the second reflecting mirror, in a direction different from that of the second reflecting mirror.