The present invention addresses the problem of providing a head-up display device with which the display quality of a display object can be improved. A mirror holder 30 supporting a concave mirror is equipped with a protruding piece that protrudes from the approximate center of the holder width, which is defined along a rotational axis, and this protruding piece is moved by a position adjustment means. Stress acting on the mirror holder from the protruding piece is uniform in the left and right directions from the center of the mirror holder. Consequently, twisting at the location of the mirror holder is significantly reduced, so the driver is able to view a display object for which distortion has been suppressed, and the display quality of the display object is improved.

According to an instruction of a display control device, a head-up display displays display information of individual types in a displayable region of a windshield. The display control device includes a type deciding unit for deciding the types of display information; and a display controller for causing the head-up display to display the display information with the types decided by the type deciding unit in the display areas of the displayable region, the display areas being provided for the individual types of display information, and to display the display guides indicating the display areas regardless of the presence or absence of the display information.

A mobile sensor apparatus includes a capture device for capturing vehicle movements of the vehicle and an interface for transmitting data relating to the vehicle movements to a head-worn visual output device. A display system includes the mobile sensor apparatus and the head-worn visual output device.

A mirror holding structure includes: a holder; at least one protrusion part provided to one of a mirror body and the holder; at least one reception part provided to the other of the mirror body and the holder and having an insertion hole in which the at least one protrusion part is to be inserted; and at least one elastic part located between an outer peripheral surface of the at least one protrusion part and an inner peripheral surface of the insertion hole and being elastic.

A vehicle window plate has a maximum value of a variation of a curvature in a vertical direction being ±7.6E-6 mm.sup.−2 or less at least within a HUD display area. The curvature preferably increases monotonically from a lower side to an upper side at least within the HUD display area.

A processor-implemented method includes: adjusting a virtual content object based on a shape of the virtual content object projected onto a projection plane; and visualizing the adjusted virtual content object on the projection plane.

A head up display for a vehicle including an imaging device configured to emit first linearly polarized light in a first direction and second linearly polarized light in a second direction perpendicular to the first direction; a polarizing reflection mirror through which the first linearly polarized light is transmitted and from which the second linearly polarized light is reflected; a second reflection mirror spaced apart from the polarizing reflection mirror and at which the first linearly polarized light transmitted through the polarizing reflection mirror is reflected to the polarizing reflection mirror; and a first reflection mirror spaced from the polarizing reflection mirror and configured to reflect the second linearly polarized light reflected from the polarizing reflection mirror to a windshield of the vehicle to produce a first image having a first length from the windshield, and to reflect the first linearly polarized light reflected from the second reflection mirror and transmitted through the polarizing reflection mirror to the windshield of the vehicle to produce a second image having a second length from the windshield different than the first length.

A refractive optical system is disposed in an optical path from a display surface to a viewing area and between a projection optical system and the viewing area. A housing receives a display device, the projection optical system, and the refractive optical system, and is provided with an opening. An opening cover has at least partially a curved portion, and is disposed in the opening so that light emitted from the display surface is incident on a convex side of the curved portion. When a light beam that is emitted from a center of the display surface and reaches a center of the viewing area is referred to as a reference light beam, a head-up display satisfies the following condition (1):

L2≦L1  (1)

where

L1 is a distance from an end on the anterior side of the observer of the refractive optical system to the opening cover, and

L2 is a distance from a position at which the reference light beam passes through the refractive optical system to the opening cover.

On the basis of information detected from a peripheral situation detecting section and information from an automatic driving support section, a display control section generates image data in which marks for driving support of an own vehicle are drawn so as to be superposed on a forward situation diagram that shows a situation at a front side. Further, from information detected by an eye detecting section and from the image data, the display control section sets a vanishing point in accordance with a height position of eyes and computes a display image. Moreover, on the basis of the information detected by the eye detecting section, the display control section causes a display image to be displayed on the front windshield glass by a HUD such that the vanishing point is set in accordance with the height position of the eyes.

A head up display for a vehicle according to an embodiment includes a display panel configured to emit an image light; a polarized light plate configured to make the image light emitted from the display linearly polarized; a reflective mirror configured to reflect the image light onto a windshield of a vehicle; a polarized light reflective mirror configured to be disposed to face the reflective mirror; and a phase delay mirror configured to convert a phase of the light inputted from the polarized light plate and reflect the converted phase to the polarized light reflective mirror, and to convert a phase of the light reflected from the polarized light reflective mirror and reflect the converted phase to the polarized light reflective mirror, thereby minimizing a width in the forward and backward direction.