JP2020046679A - Head-up display device - Google Patents

Abstract

To provide a small-size information display device capable of displaying image information as a virtual image on a windshield.SOLUTION: An information display device for displaying image information as a virtual image on a windshield of a vehicle is provided, which includes: a liquid crystal panel disposed as an image display device for forming the image information; and a virtual image optical system including the windshield for displaying the virtual image in front of the vehicle by reflecting the image of the liquid crystal panel on the windshield. The virtual image optical system is constituted by a concave mirror and an optical element disposed between the concave mirror and the image display device.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an information display device that projects an image on a windshield of an automobile, a train, an aircraft, or the like (hereinafter, also generally referred to as a “vehicle”), and observes the image as a virtual image through the windshield. The present invention relates to a projection optical system and an information display device using the same.

  A so-called head-up display (HUD: Head-Up display) that projects a virtual image on a windshield of an automobile to form a virtual image and displays traffic information such as route information and traffic information and vehicle information such as a fuel remaining amount and a cooling water temperature. -Display device is already known from US Pat.

  In this type of information display device, miniaturization is desired because the main body of the HUD device is disposed between the steering wheel in front of the driver's seat and the window glass.

  On the other hand, for example, a device for mounting a main body near the ceiling (sun visor) of an automobile as disclosed in Non-Patent Document 1 below has also been proposed.

JP 2015-194707 A

PIONEER R & D (Vol.22,2013)

  The principle of virtual image generation by a concave mirror realizing a head-up display device according to the prior art is as shown in FIG. 27, in which a point O on the optical axis of the concave mirror 1 ′ is located inside a focal point F (focal length f). By arranging the object point AB, it is possible to obtain a virtual image by the concave mirror 1 '. In FIG. 27, for the sake of explanation, the concave mirror 1 'is regarded as a convex lens having the same positive refractive power, and the object point and the convex lens (for convenience of explanation, indicated by a concave mirror in FIG. 27) are generated. The relationship was shown.

  In the prior art, the object point AB should be closer to the focal point F in order to enlarge the size of the virtual image generated by the concave mirror 1 ', but in order to obtain a desired magnification, the radius of curvature of the concave mirror becomes smaller. . As a result, the mirror size is reduced, and the effective magnification is large, but only a virtual image with a small viewable range is obtained. For this reason, in order to simultaneously satisfy (1) a desired virtual image size and (2) a required virtual image magnification M = b / a, the size of the concave mirror should be adjusted to the viewing range, and it should be balanced with the image display device. Needs to determine the magnification of the virtual image.

  For this reason, in the related art, in order to obtain a virtual image of a desired size, as shown in FIG. 27, it is necessary to increase the distance from the concave mirror 1 ′ to the virtual image, and as a result, the size of the information display device increases. I had to be.

  Further, as described above, the size of the virtual image visually recognized by the driver depends on the distance a between the image display device and the concave mirror 1 ′ and the distance b between the concave mirror 1 ′ and the virtual image caused by the inclination of the windshield. Therefore, it is difficult to make the image magnification at the upper end of the virtual image substantially equal to the image magnification at the lower end of the virtual image. For this reason, it is necessary to reduce a partial change in image magnification (image distortion) by relatively reducing the difference between the upper and lower optical paths by increasing the dimension b described above. An attempt was made to reduce the volume of the information display device by providing an optical path turning mirror between the 'and'.

  Further, the example of the head-up display device disclosed in Patent Document 1 includes a device for displaying an image and a projection optical system for projecting the image displayed on the display device. The first mirror having a first mirror and a second mirror in the optical path of the first mirror, the image major axis direction incident angle on the first mirror and the image minor axis direction incident angle on the first mirror, and the image display surface of the display device and the first mirror The relationship between the distance between the virtual image and the horizontal width of the virtual image visually recognized by the viewer satisfies a predetermined condition, thereby realizing miniaturization.

  However, as will be described later, as a result of the studies by the inventors, in order to minimize the volume of the set, the focal length of the concave mirror (122 in FIG. 2 of Patent Document 1) for creating a virtual image is reduced and the display is reduced. By shortening the distance between the position of the device and the focal point of the concave mirror, it has been found that it can be realized without a folding mirror (121 in FIG. 2 of Patent Document 1) without changing the size of the virtual image.

  On the other hand, in a device that mounts a main body near the ceiling (sun visor) of an automobile as disclosed in Non-Patent Document 1, if the HUD device comes off when a collision occurs in the automobile, the driver may be injured. The inventors have considered that the system described in Patent Document 1 will be the mainstream in the future because safety issues remain due to the nature of the system.

  Further, in Patent Document 1 described above, when there are a plurality of driver's viewpoint positions, the reflection surface of the windshield, which is the projection target member (220), has a radius of curvature in the vehicle body vertical direction and a radius of curvature in the vehicle body horizontal direction of the windshield. In view of the fact that the center position is different, as shown in all the embodiments, the optimization of the projection optical system is performed after considering the windshield as a toroidal shape.

  In the first, second, third, fourth, sixth and seventh embodiments of Patent Document 1, the two mirrors are arranged on the substantially same plane between the driver and the display device, so that the set size is reduced. In order to reduce the size of the second mirror and the second mirror having a concave reflection surface that generates a virtual image, the reflection surface of each first mirror having a convex reflection surface is used as a free-form surface. The distortion of the virtual image is reduced to a level that does not cause a problem in practical use in the entire viewpoint region.

  In the fifth embodiment, the manufacture of the mirror is facilitated by using the first mirror as a reflection surface of a toroidal surface having a convex shape. On the other hand, the second mirror is a concave mirror having a free-form surface shape as in the other embodiments.

  In the invention disclosed in Patent Document 1 described above, it is necessary to arrange two mirrors between the observer and the display device, and the light beam reflected by the first mirror is not blocked by the second mirror. In such an arrangement, the degree of freedom of arrangement is lost and it is not possible to arrange in close proximity, which hinders downsizing of the set. On the other hand, regarding the correction of the aberration generated in the virtual image viewed by the driver, the necessity of the correction and the specific reduction means are not described at all and have not been considered.

  According to the present invention, in order to realize the miniaturization of the apparatus, a mirror having a concave reflecting surface that forms a virtual image is formed as a single mirror, and at least one cross section between the driver and the display device has a concave surface. By disposing a lens (having a negative refractive power), the distortion and aberration of the virtual image visually recognized by the driver are reduced to a level at which there is no practical problem, while suppressing the enlargement and complication of the set. An object of the present invention is to provide an information display device capable of forming a virtual image.

The present invention made to achieve the above object, as an example,
An information display device that displays image information of a virtual image on a windshield of a vehicle, a flat display that displays the image information, and a plurality of virtual images by reflecting light emitted from the flat display on the windshield. A virtual image optical system for displaying in front of the vehicle, wherein the virtual image optical system includes a concave mirror and an optical element, and the optical element has a virtual image superimposed on a distant view at the top of the windshield. And from the top to the bottom of the windshield, corresponding to the image luminous flux that establishes each virtual image separated between the flat display and the concave mirror, so as to establish a virtual image overlapping the foreground. By optimizing the shape and the position of the optical element, the plurality of virtual An information display apparatus for forming an.

  According to the present invention, it is possible to provide an information display device capable of forming a highly visible virtual image in which distortion and aberration of a virtual image observed by a driver are corrected while realizing miniaturization of the device. Becomes

FIG. 2 is a schematic configuration diagram illustrating a schematic configuration of an information display device and peripheral devices assigned to the information display device. 1 is a top view of an automobile equipped with the information display device of the present invention. It is a block diagram explaining the difference of the curvature radius of a windshield. It is a schematic structure figure showing an information display device, a windshield, and a driver's viewpoint position. FIG. 2 is a schematic configuration diagram illustrating an embodiment of a virtual image optical system of the information display device of the present invention. It is a schematic structure figure showing arrangement of a virtual image optical system of an information display as an example of the present invention. It is a figure which shows the distance of the concave mirror of a virtual image optical system and the image display device of the information display device of this invention, and the dimension relationship of a device. FIG. 3 is a diagram showing a relationship between the distance between the concave mirror of the virtual image optical system of the information display device and the image display device and the volume of the device. It is a schematic diagram explaining the principle of the present invention. FIG. 2 is a configuration diagram showing an arrangement of a video display device and a light source device in the information display device of the present invention. FIG. 2 is a schematic configuration diagram illustrating a configuration of a light source device of an image display unit according to the present invention. It is a schematic structure figure showing the shape of the light guide of the light source device of the present invention. It is a schematic structure figure showing the section shape of the light guide of the light source device of the present invention. FIG. 3 is a schematic diagram illustrating the state of light emission from a video display device and a light source device in the information display device of the present invention. FIG. 4 is a characteristic diagram illustrating an emission light distribution of a light beam from a light source device for a video display device in the information display device of the present invention. FIG. 4 is a conceptual diagram illustrating a method for evaluating characteristics of a liquid crystal panel as an image display device. FIG. 4 is a characteristic diagram illustrating transmittance characteristics of a liquid crystal panel as a video display device in a horizontal direction of a screen. FIG. 7 is a characteristic diagram illustrating angle characteristics of luminance in a horizontal direction of a screen when white display is performed on a liquid crystal panel as a video display device. FIG. 5 is a characteristic diagram illustrating left-right angle characteristics of backlight luminance of a liquid crystal panel as an image display device. FIG. 4 is a characteristic diagram showing an angle characteristic of a transmittance in a vertical direction of a liquid crystal panel as an image display device. FIG. 9 is a characteristic diagram illustrating an angle characteristic of luminance in a vertical direction when a liquid crystal panel as a video display device performs white display. FIG. 5 is a characteristic diagram showing vertical angle characteristics of backlight luminance of a liquid crystal panel as an image display device. FIG. 6 is a characteristic diagram illustrating left-right angle characteristics of contrast of a liquid crystal panel as an image display device. FIG. 9 is a characteristic diagram illustrating left-right angle characteristics of black display luminance of a liquid crystal panel as an image display device. FIG. 4 is a characteristic diagram showing vertical angle characteristics of contrast of a liquid crystal panel as an image display device. FIG. 4 is a characteristic diagram showing vertical angle characteristics of black display luminance of a liquid crystal panel as an image display device. FIG. 3 is a schematic diagram for explaining the principle of a virtual image optical system according to the related art.

  Hereinafter, various embodiments of the present invention will be described in detail with reference to the drawings and the like. Note that the following description shows specific examples of the content of the present invention, and the present invention is not limited to these descriptions, and is within the scope of the technical idea disclosed in the present specification. Various changes and modifications are possible. In all the drawings for describing the present invention, components having the same function are denoted by the same reference numerals, and repeated description thereof may be omitted.

<Embodiment of information display device>
FIG. 1 is a block diagram and a schematic configuration diagram showing a peripheral device configuration of an information display device according to an embodiment of the present invention. Here, as an example, an information display device that projects an image on a windshield of an automobile is shown as an example. Will be described.

  Since the information display device 100 forms the virtual image V1 in front of the host vehicle in the driver's line of sight 8, various information reflected on the projection target member 6 (in this embodiment, the inner surface of the windshield) is used as the virtual image VI. It is a device (so-called HUD (Headup Display)) for displaying as a (Virtual Image). The projection target member 6 may be a member on which information is projected, and is not limited to the above-described windshield, but may also be a combiner. That is, in the information device 100 of the present embodiment, any information may be used as long as it forms a virtual image in front of the own vehicle in the driver's line of sight 8 and allows the driver to visually recognize the virtual image. For example, it naturally includes, for example, vehicle information and foreground information photographed by a camera (not shown) such as a surveillance camera or an around viewer. Will.

  Further, in the information display device 100, a video display device 4 that projects video light for displaying information, and a distortion or aberration generated when a virtual image is formed on the video displayed on the video display device 4 by the concave mirror 1. A lens group 2 for correction is provided between the image display device 4 and the concave mirror 1 for correction.

  The information display device 100 includes the video display device 4 and a control device 40 that controls the backlight 5. The optical components including the video display device 4 and the backlight 5 are virtual image optical systems described below, and include the concave mirror 1 that reflects light. The light reflected by the optical component 5 is reflected by the projection target member 6 and travels to the driver's line of sight 8 (Eye Box: described later in detail).

  Examples of the image display device 4 include a self-luminous VFD (Vacuum Flourescent Display) in addition to an LCD (Liquid Crystal Display) having a backlight.

  On the other hand, instead of the image display device 4 described above, an image is displayed on a screen by a projection device, and a virtual image is formed by the concave mirror 1 and reflected by a windshield 6 which is a projection target member to be directed to a viewpoint 8 of a driver. You may let it go.

  For example, such a screen may be configured by a microlens array in which microlenses are arranged two-dimensionally.

  More specifically, in order to reduce the distortion of the virtual image, the shape of the concave mirror 1 is set in the upper part shown in FIG. 1 (the area where light rays are reflected below the windshield 6 whose distance from the driver's viewpoint is relatively short). ), The radius of curvature is relatively small so that the enlargement ratio is large, while the enlargement ratio is small in the lower part (the area where light rays are reflected above the windshield 6 that is relatively long from the driver's viewpoint). It is preferable that the radius of curvature be relatively large so that is small. Further, even better correction can be realized by inclining the image display device 4 with respect to the optical axis of the concave mirror to correct the above-described difference in virtual image magnification and reducing the distortion itself.

  On the other hand, as shown in FIG. 2, the windshield 6 of the passenger car has a curvature radius Rv in the vertical direction of the main body and a curvature radius Rh in the horizontal direction, and generally has a relationship of Rh> Rv. For this reason, as shown in FIG. 3, when the windshield 6 is captured as a reflection surface, it becomes a toroidal surface of a concave mirror. For this reason, in the information display device of the present invention shown in FIG. 3, the shape of the concave mirror 1 is such that the virtual image magnification due to the shape of the windshield 6 is corrected, that is, the difference between the vertical and horizontal curvature radii of the windshield. The average radius of curvature may be different in the horizontal direction and the vertical direction so as to be corrected. At this time, the shape of the concave mirror 1 is a function of the distance r from the optical axis in a spherical or aspherical shape symmetrical to the optical axis (a shape expressed by the following equation (2)). Since the cross-section and the vertical cross-sectional shape cannot be individually controlled, it is preferable that the correction be performed as a function of the coordinates (x, y) of the surface from the optical axis of the mirror surface as a free-form surface represented by Expression 1 described below.

  Returning to FIG. 1 again, by further arranging, for example, a lens element 2 as a transmission-type optical component between the image display device 4 and the concave mirror 1, and controlling the emission direction of light rays to the concave mirror. At the same time as correcting the distortion in accordance with the shape of the concave mirror, the correction of the virtual image including the astigmatism caused by the difference between the horizontal curvature radius and the vertical curvature radius of the windshield 6 is realized. .

  Further, in order to further enhance the aberration correction ability, the above-described optical element 2 may be a plurality of lenses. Alternatively, by disposing a curved mirror instead of the lens element and controlling the incident position of the light beam on the concave mirror 1 at the same time as the turning back of the optical path, the distortion can be reduced. As described above, even if an optical element optimally designed to improve the aberration correction ability is provided between the concave mirror 1 and the image display device 4, the optical element deviates from the technical idea or scope of the present invention. Not to mention that it is not. Further, by changing the thickness of the optical element 2 in the optical axis direction, in addition to the original aberration correction, the optical distance between the concave mirror 1 and the image display device 4 is changed so that the display position of the virtual image is far away. , To the proximity position.

  Alternatively, the difference in the vertical magnification of the virtual image may be corrected by disposing the image display device 4 at an angle to the optical axis normal of the concave mirror 1.

  On the other hand, as a factor of deteriorating the image quality of the information display device, the image light beam emitted from the image display device 4 toward the concave mirror 1 is reflected by the surface of the optical element 2 disposed on the way back to the image display device, and again. It is known that the light is reflected and superimposed on the original image light to lower the image quality. For this reason, according to the present invention, not only an antireflection film is formed on the surface of the optical element 2 to suppress reflection, but also one of the image light incident surface and the exit surface of the optical element 2 or both lens surfaces. It is preferable to design the shape so that the above-mentioned reflected light does not extremely converge on a part of the image display device 4.

  Next, if the image display device 4 is a liquid crystal panel in which a polarizing plate is arranged to absorb the reflected light from the optical element 2 described above, the deterioration in image quality can be reduced. The backlight 5 of the liquid crystal panel is controlled so that the incident direction of light incident on the liquid crystal panel 4 is efficiently incident on the entrance pupil of the concave mirror 1. Further, as the light source, a solid-state light source having a long product life may be used, and furthermore, a PBS provided with optical means for reducing the divergence angle of light as an LED (Light Emitting Diode) having a small change in light output with respect to a change in ambient temperature. (Polarizing Beam Splitter) is preferably used to perform polarization conversion.

  Polarizing plates are arranged on the backlight 5 side (light incident surface) and the optical element 2 side (light emitting surface) of the liquid crystal panel to increase the contrast ratio of image light. A high contrast ratio can be obtained by using an iodine-based polarizing plate having a high degree of polarization as the polarizing plate provided on the backlight 5 side (light incident surface). On the other hand, by using a dye-based polarizing plate on the optical element 2 side (light emitting surface), high reliability can be obtained even when external light enters or when the environmental temperature is high.

  When a liquid crystal panel is used as an image display device, particularly when a driver wears polarized sunglasses, a problem occurs in which a specific polarized wave is blocked and an image cannot be seen. In order to prevent this, it is preferable that a λ / 4 plate is disposed on the optical element side of the polarizing plate disposed on the optical element 2 side of the liquid crystal panel, thereby converting image light aligned in a specific polarization direction into circularly polarized light. .

  The control device 40 outputs various types of information from the navigation system 61 such as the speed limit and the number of lanes of the road corresponding to the current position where the own vehicle is traveling, and the planned travel route of the own vehicle set in the navigation system 61. The information is acquired as foreground information (that is, information displayed in front of the own vehicle by the virtual image).

  The driving support ECU 62 is a control device that realizes driving support control by controlling a driving system and a control system according to an obstacle detected as a result of monitoring by the peripheral monitoring device 63. As the driving support control, for example, Includes well-known technologies such as cruise control, adaptive cruise control, pre-crash safety, and lane keeping assist.

  The periphery monitoring device 63 is a device that monitors the situation around the own vehicle. For example, a camera that detects an object existing around the own vehicle based on an image of the surroundings of the own vehicle, a search wave, And an exploration device that detects an object existing around the own vehicle based on the result of transmitting and receiving the vehicle.

  The control device 40 acquires such information (for example, the distance to the preceding vehicle, the azimuth of the preceding vehicle, the position where an obstacle or a sign is present) from the driving support ECU 62 as foreground information. Further, an ignition (IG) signal and vehicle state information are input to the control device 40. Of these information, the own vehicle state information is information acquired as vehicle information, for example, when a predetermined abnormal state such as the remaining amount of fuel of the internal combustion engine or the temperature of cooling water is detected. Contains warning information to represent. It also includes the operation result of the direction indicator, the traveling speed of the host vehicle, and shift position information. The control device 40 described above is activated when an ignition signal is input. The above is the description of the entire information display device system of the present invention.

<First Embodiment of Virtual Image Optical System>
Next, further details of the virtual image optical system and the image display device according to the present invention will be described below.

FIG. 2 is a top view of an automobile on which the information display device of the present invention is mounted, as described above, and a windshield as the projection target member 6 is present at the front of the driver's seat of the automobile main body 101. The windshield has a different inclination angle with respect to the vehicle body depending on the type of automobile. Furthermore, the inventors have investigated the radius of curvature in order to realize an optimal virtual image optical system. As a result, as shown in FIG. 3, the windshield differs between a horizontal curvature radius Rh parallel to the ground plane of the vehicle and a vertical curvature radius Rv perpendicular to the horizontal axis. In general, the following relationship was found between Rvs.
Rh> Rv

  It has also been found that the difference between the radii of curvature, that is, Rh relative to Rv, is often in the range of 1.5 to 2.5 times.

  Next, the inventors investigated a commercially available product regarding the inclination angle of the windshield. As a result, although it differs depending on the vehicle type, it was 20 to 30 degrees for the minicar or 1 Box type, 30 to 40 degrees for the sedan type, and 40 degrees or more for the sports type. Therefore, in the present invention, the difference between the horizontal curvature radius Rh parallel to the ground contact surface of the windshield and the vertical curvature radius Rv perpendicular to the horizontal axis and the inclination angle of the windshield are considered. A virtual image optical system was designed.

  More specifically, since the horizontal curvature radius Rh and the vertical curvature radius Rv of the windshield that is the projection target are greatly different from each other, the horizontal axis and the vertical axis of the windshield are perpendicular to the optical axis (Z axis). By providing the optical element 2 which is axially asymmetrical with respect to the various axes in the virtual image optical system, excellent aberration correction is realized.

  Next, the inventors studied the miniaturization of the information display device 100. The conditions for the study were as follows: FOV horizontal: 7 degrees, vertical: 2.6 degrees, and further, the virtual image distance was 2 m. At the beginning of the study, a concave mirror 1 for generating a virtual image (simply displayed as a plane mirror in FIGS. 5 and 6 below), a video display device 4 and a backlight 5 are used as basic components. One optical path turning mirror is arranged between the mirrors 1, and a simulation is performed using the arrangement of each member and the distance from the image display device 4 to the concave mirror 1 as parameters so that the volume of the information display device 100 is minimized. went.

  As a result, the volume when the image light from the image display device 4 was arranged so as not to interfere with each component was 3.6 liters. After that, the direct system without the turning mirror was studied for further miniaturization. The results of the study are summarized in FIGS. 5 and 6. Table 1 shows actual numerical values in FIG.

  The configuration of the virtual image optical system of the present invention will be described with reference to FIG. FIG. 5 is an overall configuration diagram showing a basic configuration for studying miniaturization in the virtual image optical system according to the first embodiment of the present invention shown in FIG. For the sake of simplicity, the optical element for correcting aberration and distortion is omitted, and the vertical cross-sectional shape is shown similarly to the window glass 6 shown in FIG. The image display device 4 is assumed to be a liquid crystal panel and has a basic configuration in which a backlight 5 is arranged. The image display device 4 arranges a displayed image at a position where a virtual image can be obtained by the concave mirror 1.

  At this time, as shown in FIG. 5, the image light R2 generated from the image at the center of the screen of the image display device 4, the image light R1 from the upper end, and the image light R3 from the lower end are respectively reflected by the concave mirror 1. Arrangement so that light does not interfere with the image display device 4 when reflected is a design constraint.

  FIG. 6 shows the concave mirror 1 and the image display device 4 (the liquid crystal panel and the backlight) with the FOV horizontal: 7 degrees and vertical 2.6 degrees at the same time, and the virtual image distance 2 m, in consideration of the above-mentioned design constraints. The volume of the information display device 100 was determined using the interval Z with 5) as a parameter. When the distance Z is 100 mm, the configuration shown in FIG. 6C is obtained. In this case, the vertical dimension of the concave mirror 1 can be minimized. When the distance Z is 75 mm, as shown in FIG. 6B, the angle α2 between the horizontal plane and the concave mirror 1 increases, and the vertical dimension of the concave mirror 1 also increases. When the distance Z is further reduced to 50 mm or less, as shown in FIG. 6A, the angle α3 between the horizontal plane and the concave mirror 1 increases, and the vertical dimension of the concave mirror 1 further increases.

  FIG. 7 shows a result of simulating the relationship between the set height and the set depth of the video display device 4 using the distance Z as a parameter. When the distance Z is reduced, the set depth can be reduced, while the set height increases. Similarly, FIG. 8 summarizes the relationship between the distance Z and the set volume L. The set volume (LCD in FIG. 8) is smaller than the space volume from the image display device 4 to the concave mirror (indicated as the optical path volume in FIG. 8). The change of the driving circuit, the light source driving circuit, and the volume of the backlight portion) changes at a distance Z of 60 mm as a boundary.

  From the above, in order to reduce the size of the information display device 100, it is necessary to realize a virtual image optical system in which the distance Z for directly enlarging the image displayed on the image display device 4 by the concave mirror is short. It has been found that the center of the image display unit 4 in the screen vertical direction needs to be disposed below the center of the concave mirror 1.

  On the other hand, in this arrangement, the distance between the video display device 4 and the upper end of the concave mirror 1 (corresponding to the light ray R1) is long, and the distance between the video display device 4 and the lower end of the concave mirror 1 (corresponding to the light ray R3) is short. . Therefore, the image display device 4 is moved in the direction of the arrow in FIG. 6A so that the image light does not interfere with (blocks light from) the image light, and the distance between the image display device 4 and the concave mirror 1 is made as uniform as possible. It is good to arrange so that.

  In the virtual image optical system of the present invention, the distortion correction of the virtual image and the aberration correction by the optical element for correcting the aberration generated in the virtual image are performed between the image display device 4 and the concave mirror 1. This will be described with reference to FIG. . That is, by arranging the image display device 4 (object point) inside the focal point F (focal length f) with respect to the point O on the optical axis of the concave mirror 1, a virtual image by the concave mirror 1 can be obtained. In FIG. 9, for the sake of explanation, the concave mirror 1 is regarded as a convex lens having the same positive refractive power, and the relationship between the object point and the convex lens (for convenience of explanation, represented by the concave mirror in FIG. 9) is shown. Indicated.

In the present invention, the optical element 2 is arranged to reduce distortion and aberration generated in the concave mirror 1. With this optical element, a transmission type optical lens or a concave mirror may be used.
(1) When entering the reflecting surface as a telecentric light flux, the refractive power of the lens or the concave mirror 1 becomes almost zero;
(2) When the image light from the image display device 4 diverges and enters the optical element, the optical element has a positive refractive power;
(3) When the image light from the image display device 4 is condensed and enters the optical element, the optical element has a negative refractive power;
In this manner, the direction (angle and position) of the light beam incident on the concave mirror is controlled, and the generated virtual image distortion is corrected. Furthermore, in the case of a transmission type optical lens, aberrations relating to the imaging performance generated in the virtual image are corrected by the interaction between the entrance surface on the image display device 4 side and the exit surface on the concave mirror 1 side.

  At this time, the size of the virtual image visually recognized by the driver is, as described above, the distance a between the image display device 4 and the concave mirror 1 and the distance b between the concave mirror 1 and the virtual image caused by the inclination of the windshield are the upper end of the virtual image. And different at the lower end.

  For this reason, the inventors tilt the image display device 4 with respect to the optical axis of the concave mirror 1 as shown in FIG. 9 so that the image magnification M ′ = b ′ / a ′ at the upper end of the virtual image and the lower end of the virtual image It has been found that it is better to reduce the generated distortion by making the image magnification M = b / a of the portion substantially equal.

  Further, the average radius of curvature of the vertical cross-sectional shape of the optical element 2 and the average radius of curvature of the horizontal cross-sectional shape are set to different values, and the above-described difference between the vertical radius of curvature Rv and the horizontal radius of curvature Rh of the windshield is determined. Distortion caused by the generated optical path difference and aberration that degrades the imaging performance of a virtual image are corrected.

  As described above, in the information display device 100 that directly reflects image light on the windshield 6 to obtain a virtual image, the optical path difference caused by the difference between the vertical curvature radius Rv and the horizontal curvature radius Rh of the windshield 6 causes Correction of the generated aberration is most important in securing the imaging performance of the virtual image.

  For this reason, the present inventors have developed an aspherical shape that defines the shape of a lens surface or a mirror surface as a function of the distance r from the optical axis, which has been used in conventional optical design (see (Equation 2) below). In contrast, by using a free-form surface shape (see the following equation 1) capable of defining the surface shape as a function of the absolute coordinates (x, y) from the optical axis, The reduction in the imaging performance of the virtual image due to the difference in the radius of curvature of is reduced.

  The aspherical shape that defines the shape of the lens surface or the mirror surface as a function of the distance r from the optical axis is expressed by the following equation (2).

  FIG. 10 is an enlarged view of a main part of the liquid crystal panel and the backlight light source 5 as the virtual image optical system image display device 4 according to the first embodiment described above. An image is displayed on the liquid crystal panel display surface 11 by modulating light from a backlight with an image signal input from the flexible substrate 10 of the liquid crystal panel, and the displayed image is displayed on a virtual image optical system (in the embodiment, a free-form concave surface). A virtual image is generated by a mirror and a free-form surface optical element, and the image information is transmitted to the driver.

  In the above configuration, a relatively inexpensive and highly reliable LED light source is used as the light source element of the backlight light source 5 as a solid-state light source. Since the LED uses a surface-emitting type in order to increase the output, the light utilization efficiency is improved by using a technical device described later. The luminous efficiency with respect to the input power of the LED varies depending on the luminescent color, but is about 20 to 30%, and most of the rest is converted to heat. For this reason, as a frame on which the LED is mounted, a radiating fin 13 made of a member having a high thermal conductivity (for example, a metal member such as aluminum) is provided to dissipate heat to the outside, thereby improving the luminous efficiency of the LED itself. The effect of improving is obtained.

  In particular, LEDs that emit red light on the market today have a large decrease in luminous efficiency when the junction temperature increases, and at the same time change the chromaticity of the image, so raise the priority of LED temperature reduction, It is preferable to adopt a configuration in which the area of the corresponding radiation fin is increased to increase the cooling efficiency. In order to efficiently guide the diffused light from the LEDs to the liquid crystal panel 4, the light guide 18 is used in the example shown in FIG. 11, but the whole is covered with an exterior member 16 so as to prevent dust or the like from adhering. It is preferable to combine them as a light source.

  FIG. 11 is an enlarged view of an essential part of the light source unit including the LED as the light source, the light guide, and the diffusion plate. As is clear from the drawing, the light funnels 21, 22, 23 , 24 for taking in the divergent light rays from the LEDs are flat surfaces, a medium is inserted between the openings and optically connected to the LEDs, or a convex shape has a light condensing function. This makes the diverging light source light as parallel light as possible to reduce the incident angle of light incident on the interface of the light funnel. As a result, since the divergence angle can be further reduced after passing through the light funnel, it is easy to control the light source light traveling toward the liquid crystal panel after being reflected by the light guide 18.

  Furthermore, in order to improve the utilization efficiency of the divergent light from the LED, the polarization conversion is performed by using PBS (Polarizing Beam Splitter) at the joint 25 between the light funnels 21 to 24 and the light guide 18 to obtain a desired polarization direction. The efficiency of the light incident on the LCD can be improved by converting to.

  When the polarization directions of the light source light are aligned as described above, a material having a low birefringence is used as the material of the light guide 18, and when the direction of polarization is rotated and passes through the liquid crystal panel, for example, during black display It is even better to avoid problems such as coloring.

  As described above, the luminous flux from the LED whose divergence angle is reduced is controlled by the light guide, reflected by the total reflection surface provided on the slope of the light guide 18, and between the facing surface and the liquid crystal panel. After being diffused by the arranged diffusion member 14, the light enters the liquid crystal panel 4 as an image display device. In the present embodiment, as described above, the diffusion member 14 is disposed between the light guide 18 and the liquid crystal panel 4. However, the light guide 18 has a diffusion effect on its end face. The same effect can be obtained even if it is provided.

  Next, the configuration of the above-described light guide 18 and the effects obtained thereby will be described with reference to FIGS. FIG. 12 is an external view showing a light guide 18 of the present invention. The luminous flux whose divergence angle has been reduced by the light funnels 21 to 24 shown in FIG. 11 is incident on the light incident surface 18a of the light guide 18 at this time, due to the shape of the incident surface (the sectional shape is shown in FIG. 13). The divergence angle in the vertical direction (the vertical direction in FIG. 13) is controlled, and the light propagates efficiently in the light guide 18.

  FIG. 13 is an enlarged cross-sectional view of a main part of the light guide. The light source light whose divergence angle is reduced by the light funnels 21 to 24 is incident from the incident surface 18a via the joint 25 as described above. The light is totally reflected by the prism 18 provided on the facing surface and travels toward the facing surface 17. The total reflection prism 18 is divided into a step-like shape in the vicinity of the incident surface 18a (enlarged view of the portion B) and at the end portion (enlarged view of the portion A) according to the divergence angle of the light beam incident on each surface. Thus, the angle of the total reflection surface is controlled. On the other hand, the divided luminous flux is used as a variable with the above-described divisional dimension of the total reflection surface so that the luminous flux incident on the liquid crystal panel 4 as an image display device becomes uniform in the light amount distribution on the exit surface of the liquid crystal panel 4. And the amount of energy after reflection of light are controlled.

  FIG. 14 shows a result of simulating a state in which the light emitted from the backlight passes through the liquid crystal panel in the information display device 100 of the present invention. FIG. 14A is a diagram showing a light emitting state as viewed from the longitudinal direction of the liquid crystal panel, and FIG. 14B is a diagram showing a light emitting state as viewed from the lateral direction of the liquid crystal panel. In the present invention, in order to widen the horizontal angle of the FOV beyond the design, the horizontal diffusion angle is increased with respect to the vertical direction. It is designed so that the brightness of the virtual image visually recognized by the eyes does not change extremely.

  Further, as in the embodiment of the present invention, the luminance distribution of the emission surface of the liquid crystal panel 4 and the evaluation of the characteristics of the liquid crystal panel when a backlight in which the light emission direction and the intensity of light are controlled using the light guide 18 are used. The method is shown in FIGS. As is clear from the drawing, the inclination of the luminance drop in the area other than the effective range in the screen vertical direction (long side direction) can be reduced with respect to the luminance distribution in the screen vertical direction (short side direction).

  In the information display device 100 of the present invention, the light emitted from the liquid crystal panel (image light) used as the image display device is ± 50 as shown in FIGS. A predetermined transmittance is shown in the range of °. If the range of the viewing angle is within ± 40 °, better transmittance characteristics can be obtained. As a result, as shown in FIG. 18 and FIG. 21, the brightness of the screen greatly differs depending on the viewing direction (viewing angle) in the horizontal direction and the vertical direction of the display screen. This is due to the angle characteristics of the backlight luminance shown in FIG. 19 and FIG.

  For this reason, the inventors set the angle of the total reflection surface of the light guide 18 and the light funnels 21 to 24 so that the light emitted from the liquid crystal panel 4 to be taken into the virtual image optical system is obtained as light as perpendicular to the screen as possible. By controlling the divergence angle of the light source light from the LED according to the above, the viewing angle characteristics of the backlight were narrowed down to a small range, thereby obtaining high luminance. Specifically, as shown in FIGS. 18 and 21, in order to obtain a high-luminance image, light within a range of ± 30 ° in the left and right viewing angles is used, and the contrast shown in FIGS. 23 and 25 is used. Taking the performance into consideration, by narrowing down to ± 20 ° or less, it was possible to obtain a virtual image using the source image with good image quality at the same time.

  As described above, the contrast performance that affects the image quality of the video display device can be reduced to what extent the luminance (in FIG. 24 and FIG. 26, indicated as black display luminance in FIG. 24 and FIG. 26) when black display is based, which determines the image quality. Is determined by Therefore, it is preferable to use an iodine-based polarizing plate having a high degree of polarization between the liquid crystal panel 4 and the backlight.

  On the other hand, by using a dye-based polarizing plate as the polarizing plate provided on the optical element 2 side (light emitting surface), high reliability can be obtained even when external light enters or when the environmental temperature is high.

When performing color display on the liquid crystal panel 4, a color filter corresponding to each pixel is provided. Therefore, when the light source color of the backlight is white, the light absorption by the color filter is large, and the loss is large. Thus, the inventors have used a plurality of LEDs, as shown in FIG. 11 above:
(1) Add a green LED that has a large contribution to brightness as compared with a case where a plurality of white LEDs are used.
(2) Add a red or blue LED to the white LED to enhance the glossiness of the image.
(3) By arranging the red, blue, and green LEDs individually, and adding a green LED that greatly contributes to brightness and individually driving the LEDs, it is possible to expand the color reproduction range and enhance the luster color. At the same time, the brightness improves.
(4) By performing the above (3), the transmittance of each color filter with respect to the peak luminance of the red, blue, and green LEDs is increased, and the overall brightness is improved.
(5) Further, as a second embodiment of the backlight, a PBS is arranged between the light funnel and the light guide to align the light with a specific polarization, thereby reducing damage to the polarizing plate on the liquid crystal panel incident side. I do. It is needless to say that the polarization direction of the polarizing plate disposed on the liquid crystal panel incident side should be the direction in which the polarized light aligned in a specific direction passes after passing through a PBS (Polarizing Beam Splitter).

  As described above, as the image light source device 4 according to the embodiment of the present invention, it is possible to provide a λ / 4 plate on the exit surface of the liquid crystal display panel to make the exit light circularly polarized. As a result, the driver can monitor a favorable virtual image even when wearing polarized sunglasses.

  Furthermore, even if the reflection film of the reflection mirror used in the virtual image optical system is formed of a metal multilayer film, the angle dependence of the reflectance is small, and the reflectance changes depending on the polarization direction (P wave or S wave). Therefore, the chromaticity and brightness of the screen can be kept uniform.

  Further, by providing an ultraviolet reflecting film or an optical member combining an ultraviolet reflecting film and an infrared reflecting film between the virtual image optical system and the windshield, even if external light (sunlight) enters, the liquid crystal display panel can be used. Further, since the polarizing plate can be reduced from its temperature rise and damage, the effect of not impairing the reliability of the information display device can be obtained.

  In addition, the virtual image optical system performs an optimal design including a difference between a curvature radius in a vehicle horizontal direction and a curvature radius in a vertical direction of a windshield, which has been a projection target member in the related art, and a windshield and an image display device or an intermediate device. A concave mirror 1 having a concave surface facing the windshield 6 is arranged between the image display units, whereby the image on the image display device is enlarged and reflected on the windshield 6. At this time, an optical element is arranged between the concave mirror 1 and the image display device 4, and an enlarged image (virtual image) of the image formed corresponding to the driver's viewpoint position is formed. The image light flux passing through the optical element disposed between the image display devices corrects distortion and aberration generated in the concave mirror 1. Therefore, it is possible to obtain a virtual image in which distortion and aberration are greatly reduced as compared with a conventional virtual image optical system including only a concave mirror.

  Further, in the present invention shown in FIG. 1, the virtual image obtained by being reflected on the upper part of the windshield 6 (the upper part in the vertical direction of the vehicle body) needs to be formed farther. Therefore, in order to favorably image the image light flux diverging from the upper portion of the image display device on which an image corresponding to the image is displayed, the optical element disposed between the concave mirror 1 and the image display device 4 described above. Is short, and conversely, the virtual image obtained by being reflected by the lower part of the windshield 6 (the lower part in the vertical direction of the vehicle body) needs to be formed closer to the virtual image. Therefore, a plurality of optical elements disposed between the concave mirror 1 and the image display device 4 in order to form an image of the image light flux diverging from the lower portion of the image display device on which the corresponding image is displayed. Is preferably set relatively long.

  Further, in the present invention, the screen distortion of the virtual image viewed by the driver is reduced by the difference between the curvature radius of the windshield 6 in the horizontal direction (parallel to the ground) and the curvature radius in the vertical direction (direction perpendicular to the horizontal direction of the windshield). In order to perform the correction, an optical element having different axial symmetry with respect to the optical axis is disposed in the virtual image optical system, thereby realizing the above-described distortion correction.

  The planar light source device suitable for use in the electronic device including the image display device according to various embodiments of the present invention has been described above. However, the present invention is not limited to the above-described embodiment, but includes various modifications. For example, in the above-described embodiment, the entire system is described in detail in order to easily explain the present invention, and the present invention is not necessarily limited to those having all the described configurations. Further, a part of the configuration of one embodiment can be replaced with the configuration of another embodiment, and the configuration of one embodiment can be added to the configuration of another embodiment. Also, for a part of the configuration of each embodiment, it is possible to add, delete, or replace another configuration.

REFERENCE SIGNS LIST 100 information display device, 101 automobile, 1 concave mirror, 2 optical element, 4 liquid crystal display panel, 5 backlight light source, 6 projected member (front glass), 7 housing, V1 virtual image , 8 eye box (eye of observer), 9 light source unit, R1 upper limit image light, R2 center image light, R3 lower limit image light, 10 flexible board, 11 image display surface, 12 frame 13 fin, 14 diffusion member, 16 exterior member, 17 emission surface, 18 light guide, 20 light funnel unit, 21 light funnel, 22 light funnel, 23 light funnel, 24 light funnel , 21a: Light funnel opening, 22a: Light funnel opening, 23a: Light funnel opening, 24a: Light funnel opening, 25: Joint (PBS).

Claims (8)

A head-up display device,
Light source,
A flat display for displaying images,
A light guide that emits light from the light source to the flat display,
A virtual image optical system for displaying light emitted from the flat display as a virtual image,
The virtual image optical system includes a reflection mirror disposed on an optical path,
The light guide has a reflection surface for reflecting light from the light source inside the light guide, and the reflection surface has a stepped surface corresponding to a divergence angle of light incident on the light guide. Has a shape divided into
The flat display is arranged to be inclined with respect to the optical axis of the reflection mirror, and arranged such that the center of the image display unit in the screen vertical direction is lower than the center of the reflection mirror,
The virtual image optical system, the average radius of curvature of the vertical cross-sectional shape and the average radius of curvature of the horizontal cross-sectional shape are different values, the shape of the reflection mirror, the upper portion has a smaller radius of curvature than the lower portion,
Head-up display device. The head-up display device according to claim 1,
A light funnel disposed between the light source and the light guide,
The light funnel has an opening that captures divergent light from the light source,
A configuration in which the opening is a plane, a medium is inserted between the light source and the opening and optically connected to the opening, or the light guide has a light collecting function for the divergent light. With the configuration having a convex surface with respect to the light source, the divergent light is converted into parallel light, the incident angle of light incident on the interface of the light funnel is reduced, and the light enters the light guide from the light funnel. Reduce the divergence angle of light,
Head-up display device. The head-up display device according to claim 1 or 2,
A light funnel disposed between the light source and the light guide, and a polarization beam splitter (PBS) that performs polarization conversion for improving the use efficiency of the divergent light is provided at a joint between the light guide and the light guide. Are placed,
Head-up display device. The head-up display device according to any one of claims 1 to 3,
The virtual image optical system, on the optical path, comprising an optical element disposed between the flat display and the reflection mirror,
The virtual image obtained by being reflected on the upper portion of the windshield of the vehicle is formed in a direction farther from the viewpoint of the driver than the virtual image obtained by being reflected on the lower portion. The optical distance is such that the optical distance at the top of the optical element through which the image light flux from the top of the flat display passes is shorter than the optical distance at the bottom of the optical element through which the image light flux from the bottom passes. Is set to be
Head-up display device. A head-up display device for a vehicle,
Light source,
A flat display for displaying images,
A light guide that emits light from the light source to the flat display,
A virtual image optical system for displaying light emitted from the flat display as a virtual image,
The virtual image optical system includes a reflection mirror disposed on an optical path,
The light guide has a reflection surface for reflecting light from the light source inside the light guide, and the reflection surface has a stepped surface corresponding to a divergence angle of light incident on the light guide. Has a shape divided into
The flat display is arranged so as to be inclined with respect to the optical axis of the reflection mirror, and is arranged such that when mounted on the vehicle, the center of the image display unit in the screen vertical direction is lower than the center of the reflection mirror. And
The virtual image optical system, the average radius of curvature of the vertical cross-sectional shape and the average radius of curvature of the horizontal cross-sectional shape are different values, the shape of the reflection mirror, the upper portion has a smaller radius of curvature than the lower portion,
Head-up display device. The head-up display device according to claim 5,
A light funnel disposed between the light source and the light guide,
The light funnel has an opening that captures divergent light from the light source,
A configuration in which the opening is a plane, a medium is inserted between the light source and the opening and optically connected to the opening, or the light guide has a light collecting function for the divergent light. With the configuration having a convex surface with respect to the light source, the divergent light is converted into parallel light, the incident angle of light incident on the interface of the light funnel is reduced, and the light enters the light guide from the light funnel. Reduce the divergence angle of light,
Head-up display device. The head-up display device according to claim 5 or 6,
A light funnel disposed between the light source and the light guide, and a polarization beam splitter (PBS) that performs polarization conversion for improving the use efficiency of the divergent light is provided at a joint between the light guide and the light guide. Are placed,
Head-up display device. The head-up display device according to any one of claims 5 to 7,
The virtual image optical system, on the optical path, comprising an optical element disposed between the flat display and the reflection mirror,
In the optical axis direction of the optical element, the virtual image obtained by being reflected at the upper portion of the windshield of the vehicle is formed farther from the viewpoint of the driver than the virtual image obtained by being reflected at the lower portion. The optical distance of the optical element at the top of the optical element through which the image light flux from the top of the flat display passes, is smaller than the optical distance at the bottom of the optical element through which the image light flux from the bottom passes. Set to be shorter,
Head-up display device.

Images