JP3631318B2 - Liquid crystal display device and head mounted video display device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a liquid crystal display device having excellent visibility even when observed from a large elevation angle with respect to the normal line of the display surface.
[0002]
[Prior art]
In recent years, liquid crystal panels featuring low power consumption as display elements for video display devices, and directivity with emission light distribution similar to back-illuminated parallel light as light sources with high illumination efficiency to minimize power consumption as much as possible A liquid crystal display device provided with an excellent backlight is used. The liquid crystal display device having such a configuration has viewing angle dependency. That is, the visibility of the screen varies depending on the angle of suppression to be observed, and the display can be seen only within a specific angle range. This is because the transmissivity of the liquid crystal panel changes depending on the incident angle of the light beam with respect to the orientation of the liquid crystal molecules, and the transmissivity extremely deteriorates in a certain direction. In addition, when the liquid crystal display device is illuminated with a directional backlight, the light incident on the liquid crystal panel travels substantially straight due to the emission light distribution of the backlight. Therefore, when the display surface is observed from an oblique direction, the amount of light emitted in that direction Are relatively few. For this reason, the contrast when the liquid crystal display device having viewing angle dependency is observed obliquely is lowered. Or the contrast of a peripheral part worsens locally and there exists a malfunction that visibility deteriorates.
[0003]
In a normal liquid crystal panel, the visible viewing angle range is about ± 10 ° from the normal direction (see FIG. 30C), and the display density is inverted when observed in an elevation angle region beyond this range. Or the color will change. The following techniques are disclosed as a method for solving this problem.
A member for increasing the numerical aperture NA of the image (hereinafter referred to as a numerical aperture increasing member) is provided on the viewer side of the liquid crystal panel to reduce the viewing angle dependency. That is, in order to increase the contrast of the image and the light use efficiency, the light beam from the illumination light source is made into a substantially parallel light beam and then vertically incident on the liquid crystal layer, and the light that has traveled straight through the liquid crystal layer is provided on the exit side of the liquid crystal panel. It is scattered, refracted, or diffracted by a member that increases the number and guided to the observer's eyeball. Here, the numerical aperture increasing member specifically includes a diffuser plate that uses light scattering action, a microlens that uses light refraction action, and a diffraction grating that uses light diffraction action.
[0004]
[Problems to be solved by the invention]
However, the conventional example using the numerical aperture increasing member as described above has the following problems.
First, in the example using a diffusion plate, light is diffused by unevenness on the surface or inside of the plate, so that the light is scattered in a direction that easily enters the eyeball of the observer and in a direction that is difficult to enter in the unevenness. As a result, a portion that scatters light in a direction that easily enters the eyeball appears bright, and a portion that does not look dark appears to be dark. That is, from a minute viewpoint, the light scattered on the viewer side is not uniform, and the image is shaded. This is because the surface of a diffusion plate containing fine particles or a glass plate is chemically and physically roughened, and although it is a substantially diffusing surface, it is difficult to obtain a completely diffusing surface in production. Because.
[0005]
Further, in the example using the micro lens, as shown in FIG. 30A, when the pixel 301 is arranged at the focal length position of each lens 302, the distribution of the brightness of the image is uniform. Even if it can be improved in the direction in which the image is displayed, the improvement in view angle, that is, whether the image can be visually recognized while maintaining the contrast even when viewed from the maximum with respect to the display surface is not so effective. When the value of θ, which is an effect of widening the viewing angle, is obtained using each practical numerical value, when the pixel aperture of the LCD is 30 μm and the focal length of the microlens 302 is 1 mm, θ in the figure is 1. Since 7 °, the effect is low. In addition, as shown in FIG. 30B, when the pixel 301 is arranged at a position away from the focal length of the micro lens 302, there is an effect of widening the viewing angle. When the viewing angle expansion effect is obtained using practical numerical values, when the pixel aperture of the LCD is 30 μm, the focal length of the microlens 302 is 1 mm, and the distance between the pixel 301 and the lens 302 is 5 mm, α = 0.286 °, β = 1.432 °, and the viewing angle is enlarged, but the effect of enlargement is small although it requires space.
[0006]
Further, in the example using the diffraction grating, the wavelength dependence peculiar to the diffraction action is accompanied, and the color unevenness appears in the image. In addition, no image can be seen except in the direction of each diffraction order that meets the diffraction conditions.
In addition to the technique of bending the light on the exit side of the liquid crystal panel and increasing the numerical aperture after making the light substantially parallel, the image of the liquid crystal panel is relayed once using a lens and A technique for increasing the numerical aperture by installing the numerical aperture increasing member as described above and consequently widening the viewing angle is disclosed.
[0007]
This technique improves the following problems that always occur in the structure of the liquid crystal panel when the image of the liquid crystal panel is not relayed using a lens.
As shown in FIG. 31, the liquid crystal panel has a structure in which a polarizing plate 311, a glass plate 312, a transparent electrode plate 313, a liquid crystal layer 314, a transparent electrode plate 315, a color filter 316, a glass plate 317, and a polarizing plate 318 are overlaid. have. Furthermore, the liquid crystal layer 314 is separated into pixel units called liquid crystal cells by an electrode plate having transistors. At this time, an image portion hits each liquid crystal cell, but since there is a glass plate 317 having a finite thickness on the emission side of the liquid crystal cell, the light is bent further on the emission side of this glass plate 317 so that the numerical aperture is increased. When the member to be raised is installed, the light beam emitted from the adjacent liquid crystal cell enters the eyeball of the observer at the same time, and the image is blurred. In order to improve this, a lens is used to relay an image once, and a member that raises the numerical aperture by bending light at the position of the relayed image is installed to create an image with a wide viewing angle without blurring. Can do.
[0008]
However, since this technology relays an image once, it requires a lens to be relayed and a space required for the relay, so the advantage of being able to have a flat structure that does not take up space, which is one of the features of a liquid crystal display device, is reduced. It will end up.
The present invention has been made in view of the above-described problems of the related art, and an object of the present invention is to provide a liquid crystal display device having a large viewing angle without reducing display contrast.
[0009]
[Means for Solving the Problems]
The present invention provides an illuminating unit that generates a substantially parallel light beam, a liquid crystal display element that displays a video image by the incident light beam from the illuminating unit, and the liquid crystal display on an optical path of an image light beam emitted from the liquid crystal display element. A numerical aperture increasing member disposed in the vicinity of the element for diffusing the image light flux, and the numerical aperture increasing member is formed by bundling optical fibers in a direction perpendicular to the length direction into a plate shape Thus, the liquid crystal display device is characterized in that the reflection boundary surface inside each optical fiber has an uneven shape.
[0010]
The present invention also relates to an illuminating unit that generates a substantially parallel light beam, and a liquid crystal display element that displays an image when the light beam is incident from the illuminating unit.And furtherIt is disposed in the vicinity of the liquid crystal display element on the optical path of the image light beam emitted from the liquid crystal display element, and diffuses the image light beam.At least two numerical aperture increasing surfaces selected from a diffusion plate, a diffraction grating, and a prism arrayA liquid crystal display device comprising the liquid crystal display device.
[0011]
The present invention also provides any one of the liquid crystal display devices, an eyepiece optical system that projects an image displayed on the liquid crystal display device onto an eyeball of an observer, and the liquid crystal display device and the eyepiece optical system as an observer. A head-mounted image display device comprising a head mounting means positioned immediately before the eyeball.
According to the present invention or an embodiment thereof, a substantially parallel light is incident on the liquid crystal display element, and the numerical aperture is increased after passing through the liquid crystal display element, thereby reducing the field of view while maintaining the contrast without reducing the illumination efficiency. The possible range can be expanded.
[0012]
Further, since the scattering type liquid crystal device is used as the numerical aperture increasing member, the dynamic scattering state can be obtained by applying a voltage, so that the transmission state and the scattering state can be electrically controlled. As a result, a desired image can be obtained by setting the transmission state when priority is given to resolution in the viewing angle and resolution that are in a trade-off relationship, and setting the scattering state when widening the viewing angle. Further, by forming a transparent electrode for applying a voltage signal into a matrix, the degree of scattering, that is, the numerical aperture can be provided with a gradation.
[0013]
Further, in the above, if the numerical aperture increasing member is constituted by a prism array, it is possible to obtain an effect of increasing the viewing angle while suppressing the cost from the production surface of the element as compared with a diffraction grating or the like. Further, the viewing angle can be changed according to the apex angle of the prism to be manufactured.
Alternatively, a reflecting surface for diverging and reflecting the luminous flux of each pixel emitted from the liquid crystal display element through the numerical aperture increasing member toward the liquid crystal display element and a reflecting surface for reflecting the divergent reflected luminous flux in the image display direction, respectively If a plurality of arrangements are arranged corresponding to the pixel pitch of the liquid crystal display element in a state of being opposed by a predetermined distance, the reflecting surface to be diffusely reflected has a curvature, or the interval between the diverging reflecting surface and the planar reflecting surface is changed. This makes it possible to increase the numerical aperture.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described with reference to the drawings illustrating embodiments thereof.
(Embodiment 1)
FIG. 1 is a schematic configuration diagram of a liquid crystal display device according to a first embodiment of the present invention.
[0015]
The liquid crystal display device according to the present embodiment includes a liquid crystal panel 3 as a liquid crystal display element, a point light source 1, a collimator lens 2 that makes a light beam emitted from the point light source 1 substantially parallel and vertically enters the liquid crystal panel 3. The numerical aperture increasing member 4 is disposed in close contact with the vicinity of the emission side of the liquid crystal panel 3. Although the expression “substantially parallel light” is used here, in the following embodiments, the illumination system may have a low numerical aperture (NA).
[0016]
A liquid crystal display element has a laminated structure in which a liquid crystal layer is sandwiched from above and below by a substrate provided with a liquid crystal layer at the center, and transparent electrodes to be pixel electrodes in a matrix, and polarizing plates are provided above and below the electrodes. In the case of a TN liquid crystal, contrast can be produced by an applied voltage if the polarizing plates are shifted by 90 ° in the vertical direction. A large number of pixel pitches are formed on the display side of the liquid crystal layer through an opaque mask. The opaque mask portion is provided with the electrodes, lead wires, and the like, and is formed so as to maintain an insulating interval that does not affect adjacent pixels. Further, a color filter having openings arranged with regularity can be provided on the display side so that a color image can be displayed.
[0017]
In the present embodiment, an example in which a scattering liquid crystal device is used as the numerical aperture increasing member 4 is shown. 2A shows a transmission state in the scattering liquid crystal device 20, and FIG. 2B shows a scattering state. A DS (Dynamic Scattering) mode (mechanism for scattering light) of the scattering liquid crystal device 20 will be described. By adding an ionic dopant to the p-type SmA liquid crystal, when a voltage 21 is applied to the liquid crystal, a space charge is generated in the distorted portion in the horizontal direction due to the anisotropy of the conductivity of the liquid crystal. As a result, an electrical torque is generated, and a liquid crystal vortex 22 is generated. This vortex 22 further amplifies the distortion and increases the number of vortices 22 and their strength. Since the liquid crystal has birefringence, this vortex becomes the center for scattering light. As shown in FIG. 2B, the light beam 23 emitted from the liquid crystal display element substantially in parallel is scattered by the scattering state of the scattering liquid crystal 20, and the numerical aperture of the image of the liquid crystal display element is increased. FIG. 2C is a characteristic curve showing the relationship between the applied voltage and the scattering state in the scattering liquid crystal device 20. Here, if the transparent electrodes to which the voltage 21 is applied are arranged in a matrix, a scattering state and a transmission state can be created at the same time, and the total numerical aperture increase can be varied.
[0018]
Usually, when increasing the numerical aperture, the brightness becomes darker when the numerical aperture is increased. However, the merit of the present embodiment is that the numerical aperture can be varied by increasing or decreasing the applied voltage. Therefore, it can be brought close to the desired numerical aperture within the required brightness depending on the use situation.
(Embodiment 2)
FIG. 3 is a schematic configuration diagram of a liquid crystal display device according to a second embodiment of the present invention.
[0019]
In the present embodiment, the prism array 31 is used as the numerical aperture increasing member. This prism array 31 may be one in which small and long prisms are arranged as shown in FIG. 4B, or a pyramid-like one arranged in a plane as shown in FIG. 4A. FIG. 5 shows a state where a light beam is incident on the prism array 31 and spreads. The light 32 coming out of the liquid crystal element and entering in parallel is refracted and emitted from the prism surface 31a. As a result, the light is refracted by each surface and emitted in two directions. Here, the bending angle θ ′ of the light beam depends on the incident angle of the light beam, and the bending angle θ ′ of the light beam increases as the prism apex angle Θ decreases. A relational expression among the bending angle θ ′ of the light beam, the prism apex angle Θ, the refractive index n of the member, and the incident angle θ of the light beam on the member is expressed by (Equation 1).
[0020]
[Expression 1]
θ ′ = Θ−Cos^-1[NCos [(Θ / 2) -Sin^-1[(1 / n) Sinθ]]]
For example, when the member is glass having a refractive index of 1.5 and Θ is 140 °, the vertically incident light beam is emitted with an opening of 21.73 °. In addition, as shown in FIG. 6, the same effect can be obtained by turning upside down.
[0021]
FIG. 7 shows various member shape variations. In these shapes, since the top or bottom is cut into a flat surface, there is a light beam that is transmitted without being refracted. As a result, the light beam spreads in three directions after passing through this member.
(Embodiment 3)
FIG. 8 is a schematic cross-sectional view of a liquid crystal display device according to a third embodiment of the present invention.
[0022]
In the present embodiment, the half mirror 82 as a reflecting surface for diverging and reflecting the luminous flux emitted from the liquid crystal display element as the numerical aperture increasing member for each pixel 83 toward the liquid crystal display element side, and the luminous flux divergently reflected by the reflecting surface A configuration including a mirror 81 as a reflecting surface (in this case, a flat surface) that reflects light toward the viewer is used. In FIG. 8, the divergent reflecting surface 82 has a curvature, and the reflecting surface 82 having this curvature and the planar reflecting surface 81 that reflects the light flux from the reflecting surface 82 again are alternately shifted with each other at the pixel pitch. They are lined up and held between transparent materials with little light loss. Alternatively, the same structure may be realized by applying a reflective coating at a pixel pitch on the upper and lower sides of the glass substrate of the liquid crystal panel. A description will be given of how the luminous flux is spread by the structure and the NA (numerical aperture) is increased.
[0023]
As shown in FIG. 8, a divergent reflecting surface 82 having a curvature will now be described as an example having a transmittance (half mirror). Of the light beams emitted from each pixel 83, the light beam emitted from the center of the pixel passes through the half mirror 82 and travels straight, but the light beam emitted from a portion other than the center of the pixel 83 is partially reflected by the half mirror 82. The light travels straight through, partially reflects, travels toward the lower planar reflecting surface 81, reflects off the planar reflecting surface 81, and then exits at a certain angle. At this time, each parameter in the figure: focal length f of half mirror 82, thickness t of this member, opening size X of pixel 83, pixel pitch p, light emission angle θ, effective diameter D of half mirror 82, pixel 83 Expressions relating the displacement x from the center at (Equation 2) and (Equation 3) are as follows.
[0024]
[Expression 2]
θ = Tan^-1(X / f)
[0025]
[Equation 3]
p-D / 2-X / 2 ≧ 3tTanθ
Here, (Equation 2) is an expression representing how much angle the light beam is emitted from, and (Equation 3) is again the next half after the light beam is reflected by the plane reflecting surface 81. This is a conditional expression that does not enter the mirror 82. In order to enlarge the viewing angle, it is preferable to satisfy (Equation 3).
[0026]
FIG. 9 shows other variations. FIG. 9A shows an example in which the half mirror 82 in FIG. 8 is replaced by a mirror 91, and FIG. 9B shows an example in which the half mirror 92 is not given a curvature. This may also be a mirror 93 as shown in FIG. Further, in the case where the half mirror has a curvature, the convex surface is illustrated in the figure, but a concave surface may be used. In any case, passing through this member causes the substantially parallel light beam to exit with a certain spread, resulting in an increase in the numerical aperture.
(Embodiment 4)
FIG. 10 is a perspective view showing two examples of the optical fiber plate used in the liquid crystal display device according to the fourth embodiment of the present invention. In the present embodiment, a member obtained by cutting the optical fiber 101 (or 102) into a numerical aperture increasing member and bundling it in a direction perpendicular to the length direction is used. Here, as shown in FIG. 11B, the boundary portion between the core 111 and the clad 112 in the structure of the optical fiber is a minute unevenness 113 (the boundary portion of a normal optical fiber is that shown in FIG. 11A). So that it is flat). Each optical fiber may have a circular cross section (see FIG. 10A) or a square shape (see FIG. 10B). The circular shape is inexpensive for producing an optical fiber, and is preferable for reducing the price. On the other hand, in the case of a square, each pixel is square, which is suitable for efficiently collecting emitted light.
[0027]
A state in which the numerical aperture of the LCD image increases after passing through this member is shown in FIG. Since the length of the optical fiber is short, the number of reflections is small. Therefore, the light loss is small. When reflected, the light flux spreads by the irregularities 113 on the boundary surface, and as a result, the numerical aperture increases at the optical fiber exit end. At this time, it is desirable that the unevenness 113 is uneven so that the relationship between the incident angle and the exit angle is not broken.
(Embodiment 5)
As a fifth embodiment, in the numerical aperture increasing member in which the optical fibers described in the fourth embodiment are bundled into a plate shape, the irregularities on the boundary surface between the core 111 and the clad 112 are regular in the wavelength order. Some are shown in FIG. That is, the boundary surface is the diffraction surface 121. The light beam incident on each fiber propagates while being reflected, but is diffracted when reflected and becomes a light bundle having a spread by the diffraction angle. When the reflection is repeated a plurality of times, it is diffracted each time. As a result, the spreading numerical aperture is increased at the fiber exit end.
[0028]
When a diffraction grating is used to increase the numerical aperture, there is a problem of color misregistration due to diffraction. The element of the present embodiment also causes a color shift due to the diffractive surface, but since diffraction occurs every time it is reflected, the light flux exits with various exit angles for each color at the exit end. Almost inconspicuous.
(Embodiment 6)
As a sixth embodiment, an example in which a diffraction grating 131 having unevenness 132 as shown in FIG. The diffraction effect caused by the regularity of the diffraction grating 131 and the diffusion effect caused by the irregularity of the irregularities 132 are simultaneously generated by one member to disperse the light flux. The production may be performed by putting a grain in the diffraction grating 131, chemically roughening the surface, or providing the diffusion plate with a certain degree of regularity by etching.
The production method differs depending on which action is important. The advantage of this type of element is a certain degree of control over the spread of the light beam that is not possible with a diffuser. The direction in which light is strongly guided can be controlled by the grating pitch. Further, the diffraction grating has the effect of spreading light in that direction and blurring chromatic aberration.
[0029]
As an example, when the pitch of the grating is 3 microns, the first-order diffraction angle is about 10 ° at a wavelength of 0.5 nanometer, but the surface roughness is 50 with respect to the light intensity in the direction perpendicular to the plate. If the surface has irregularities such that the diffusion angle due to surface roughness at 5% light intensity is 5 °, a uniform emission light distribution can be obtained within a range of about ± 15 °.
(Embodiment 7)
As a seventh embodiment, an example in which the viewing angle dependency can be reduced by combining a plurality of surfaces that increase the numerical aperture will be described. FIG. 14 is a diagram showing an example of the present embodiment in which the diffraction grating 141 and the diffusion plate 142 are combined. The diffraction grating 141 in FIG. 14 emits 0th order light and 1st order light. In the drawing, the diffraction grating 141 and the diffusion plate 142 are drawn apart from each other for the sake of clarity. However, in actuality, arranging them in contact with each other does not take up space and is not lost. Further, as an important point, the amount of blur is reduced. The front and back surfaces of the single element may be used as a diffraction grating surface and a diffusion surface, respectively. With this configuration, the element may be a single plate. The substantially parallel light that has passed through the LCD 143 is diffracted in the direction of the angle satisfying the diffraction condition by the diffraction grating 141 disposed immediately after the LCD 143, and each light beam is diffused by the diffusion plate 142 disposed immediately after the diffraction grating 141. Is done.
[0030]
Here, the difference in the effect depending on the order of the arrangement of the diffraction grating 141 and the diffusion plate 142 with respect to the LCD 143 will be described. FIG. 15A shows a state where the light beam spread by the diffusion plate 142 forms an image on the retina of the eyeball 151, and FIG. 16A shows a state where the light beam spread by the diffraction grating 141 forms an image on the retina of the eyeball. Shown in The diffusing plate 142 has a function of forming a large number of images of the light source 145 as shown in FIG. 15B to form a spread surface light source, whereas the diffraction grating 141 is shown in FIG. 16B. Thus, considering up to ± 1st order light, it has the effect of making two copies of the light source. When these elements are combined, a difference occurs depending on the order of the elements.
[0031]
17 and 18 are examples in which the diffraction grating 141 is disposed on the LCD 143 side and the diffusion plate 142 is disposed on the eyeball side. FIG. 17B (small interval) and FIG. 18B (large interval) show how the appearance differs depending on the interval between the diffraction grating 141 and the diffusion plate 142. The interval between the images due to the diffraction of the pixels does not change depending on the interval between the elements, and the blur due to the diffusion of each diffraction image spreads in proportion to the interval between the elements. That is, the characteristics of the diffusion plate 142 are easy to appear, such as darkening when the spacing between elements is large.
[0032]
On the other hand, FIGS. 19 and 20 are examples in which the diffraction grating 141 is disposed on the eyeball side and the diffusion plate 142 is disposed on the LCD 143 side. FIG. 19B (small interval) and FIG. 20B (large interval) show how the appearance differs depending on the interval between the diffusion plate 142 and the diffraction grating 141. Pixels spread by the diffusion plate 142 are dispersed by the diffraction grating 141 in the 0th, 1st, and −1st order directions. Therefore, the spread amount spread by the diffusion plate 142 is constant regardless of the spacing between elements, and the spread due to diffraction is proportional to the spacing between elements. Therefore, in this arrangement, the characteristics of the diffraction grating 141 are easy to be obtained, and it is easy to be colored. If the interval is too wide, it will appear colored depending on the position of the eyeball.
[0033]
In any of the arrangements, if the element arranged on the LCD 143 side is far from the pixel of the LCD 143, a phenomenon such as blurring to an adjacent pixel occurs, so it is important to make it as close as possible. Further, as shown in FIG. 21, it is important that the distance between the elements is close because it causes double images and multiple images. In that sense, a configuration in which both surfaces of the single plate are diffractive surfaces and diffusing surfaces is preferable. In the figure, it is shown that the images of A1 to C1, A2 to C2, and A3 to C3 are simultaneously seen on the retina and become a triple image when the order is 0th order and ± 1st order.
[0034]
In addition, the diffraction grating can have a desired diffraction angle and diffraction efficiency by selecting an appropriate pitch, cross-sectional shape and groove depth in consideration of the balance with the diffusion angle of the diffusion plate.
As an example, when the effective viewing angle of the LCD is ± 10 °, the viewing angle can be improved by setting the pitch so that the diffraction angle is ± 10 ° or more. For example, if the pitch of the diffraction grating is 2 μm, the diffraction angle becomes ± 15 ° when the 0th order light and the 1st order light are used. When the diffusion angle of the diffusion plate to be combined is 5 °, the viewing angle is improved to ± 30 ° as a result. When the viewing angle is expanded by these two types of members, it is desirable that the respective members and the liquid crystal panel be arranged as close as possible to prevent image deterioration due to blur. Now, assuming that the pixel pitch of the LCD is P, the allowable blur amount is P. The diffraction angle of the first-order diffracted light with respect to the zeroth-order diffracted light by the diffraction surface of the diffraction grating is θ₁  And a diffusion angle that is 50% of the intensity of transmitted light in the direction perpendicular to the diffusion surface in the diffusion plate is θ₂  And the distance from the LCD to the diffraction grating is L₁, The distance from the diffraction grating to the diffusion plate is L₂Then, the allowable relational expression of the blur amount is
[0035]
[Expression 4]
P> L₁Tanθ₁+ L₂Tanθ₂
Therefore, each parameter is controlled to satisfy this relational expression. Although the diffracting surface and the diffusing surface have been described as elements such as a diffraction grating and a diffusion plate, surfaces having various functions may be provided on both sides of a single plate.
[0036]
The meaning of combining the surfaces having different functions to spread the light fluxes is that there are two problems: only the diffraction grating surface produces a color that is unique to the diffraction function, and that the image is dark at angles other than those satisfying the diffraction conditions. This is an effect of a combination that cannot be achieved by a single substance, such as a problem that the density is reduced by the diffusing action of the diffusing surface, and the inconvenience that light and shade appears only on the diffusing surface is also weakened by the diffractive action. This can improve both the spread of the viewing angle and the angle dependency.
[0037]
Next, FIG. 22 shows an example in which a prism array and a diffusion surface are combined as a numerical aperture increasing surface.
This combination also aims at a synergistic effect by combining different light spreading conditions as described above. Also in this case, in order to make it easy to understand, in the figure, the surfaces are constituted by separate members as the prism array 221 and the diffusion plate 142, and the distance between the two is intentionally separated. The substantially parallel light that has passed through the LCD 143 enters the prism array 221, and the light beam is refracted and separated in three directions by the incident surface.
Thereafter, the respective light beams enter the diffusion plate 142 and are each subjected to a diffusing action. As a result, the viewing angle is widened and the angle dependency is reduced. The same effect can be expected regardless of the order of the positions of the prism array 221 and the diffusion plate 142.
[0038]
Next, FIG. 23 shows an example in which a prism array and a diffraction grating surface are combined as a numerical aperture increasing surface.
In the figure, for the sake of simplicity, it is assumed that the surface is composed of a prism array 221 and a diffraction grating 141, and the distance between these elements is drawn apart. Disappear. Also, as an important point, blurring and multiple images are reduced. The same effect can be obtained even if each working surface is applied to both sides of a single plate. The substantially parallel light flux that has passed through the LCD 143 passes through the prism array 221 and is emitted with an angle based on the apex angle of the surface of the prism array 221. In the shape of the prism array 221 in the figure, the light beam is separated in three directions. Thereafter, each light beam incident on the diffraction grating 141 is diffracted in a direction based on the diffraction conditions. As a result, the viewing angle is widened and the angle dependency is reduced. The same effect can be expected regardless of the order of the positions of the prism array 221 and the diffraction grating 141. Thus, the effect of the combination of the two elements (surfaces) is that the wavelength dependency can be improved. Since the prism array 221 bends the light by the refracting action of the light, while the diffraction grating 141 separates the light by the diffracting action, the direction of dispersion is opposite in both. Therefore, the color appearance is weaker than when used alone.
[0039]
Next, FIG. 24 shows an example in which three types of surfaces, a prism array, a diffraction grating surface, and a diffusion surface, are combined as the numerical aperture increasing surface.
Thus, by combining three types of surfaces having different light spreading conditions, the effect of the two types of surfaces described above is further enhanced. Also in this case, it is desirable to arrange the three types of elements (surfaces) as close as possible in order to reduce blur. In the figure, the prism array 221, the diffraction grating 141, and the diffusion plate 142 are arranged in this order as viewed from the LCD 143, but the same effect can be expected regardless of the arrangement order.
[0040]
FIG. 25 is a diagram illustrating an example in which two types of diffusion surfaces having different diffusion effects are combined as the numerical aperture increasing surface.
In the figure, for the sake of simplicity, two diffusion plates 142a and 142b are shown, and the interval between the diffusion plates is drawn apart. However, in actuality, placing them in close contact will not take up space and will not be damaged. Further, as an important point, the amount of blur is reduced. In addition, a configuration in which both sides of the single plate are diffusion surfaces is desirable for eliminating a space and making a simple configuration. The diffuser plate 142a having a rough surface uneven structure has a large viewing angle widening effect, but has a large angle dependency. On the other hand, the diffusing plate 142b having a fine surface uneven structure has a small viewing angle expansion effect but a small angle dependency. Each light spreading condition is shown in FIGS. 26 (a) and 26 (b). That is, by combining two sheets (two surfaces), a liquid crystal display device having a larger viewing angle and a smaller angle dependency, that is, a light and shade difference can be obtained.
[0041]
Next, FIG. 27 shows an example in which an element having a structure in which a plurality of diffusion surfaces are layered is used as the numerical aperture increasing surface. A plurality of diffusion plates (diffusion surfaces) are integrated into one element. In the figure, (i), (b), and (c) are preferably made of a material having a refractive index that gradually decreases from (d) because total reflection is less likely to occur. The divergence angle can be controlled by the roughness, roughness, layer thickness, and number of layers.
(Embodiment 8)
In the eighth embodiment, on the optical path for displaying the image of the liquid crystal display element, in the vicinity of the surface conjugate with the display element formed by the microlens array arranged in the vicinity of the liquid crystal display element. The example which arrange | positions each numerical aperture increasing member (or numerical aperture increasing surface) demonstrated by 1 and arranges a viewing angle expansion and angle dependency is shown. FIG. 28 shows an example in which a scattering liquid crystal is used as the numerical aperture increasing member. Here, the microlens array 282 has a lens pitch that matches the pixel pitch of the liquid crystal display element 3 and is aligned with the pixel electrode, so that the conjugate image is an erect image. By setting the focal length and numerical aperture of the lens to appropriate values, a conjugate image member can be arranged without taking up much space. As an effect of relaying the image, the image can be relayed once by the lens, and the scattering liquid crystal device 281 can be arranged as a numerical aperture increasing member (a numerical aperture increasing surface) in the relayed conjugate image position just. It is. This can improve the viewing angle dependency without blurring.
[0042]
Here, the scattering liquid crystal device 281 has been described as an example of the numerical aperture increasing member (the numerical aperture increasing surface), but the same applies to the other numerical aperture increasing members (surfaces) such as the prism array and the optical fiber plate described above. The effect can be expected.
(Embodiment 10)
FIG. 29A shows an example in which the liquid crystal display devices having various viewing angles according to the above embodiment are used as image display elements of a head device type image display device. That is, the liquid crystal display device of the present invention is used as the left and right eye display portions 291 and 292 attached to the front surface of the mounting frame 293 of the video display device. There is a field such as virtual reality as an example of use of a head-mounted image display device, but it is indispensable to have a wide angle of view in order to improve the presence. The wider the angle of view, the wider the viewing angle of the image display element is required (see FIG. 29B). When the distance between the final surface of the eyepiece optical system 295 of the head-mounted image display device and the pupil of the observer is constant, the viewing angle of the element 294 and the image necessary for viewing the image in a good state The angle of view is approximately proportional. For example, when the angle of view is 30 °, the required viewing angle is ± 8 °, but when the angle of view is 60 °, the required viewing angle is ± 16 °. In such a head-mounted image display device with a wide angle of view, it is desirable that the viewing element has a wide viewing angle.
[0043]
As mentioned above, although this invention was demonstrated based on embodiment, the following invention is contained in this specification.
That is, (1) an illuminating unit that generates a substantially parallel light beam, a liquid crystal display element that displays an image by entering the light beam from the illuminating unit, and the liquid crystal on an optical path of an image light beam emitted from the liquid crystal display element And a numerical aperture increasing member disposed in the vicinity of the display element for diffusing the image light flux, wherein the numerical aperture increasing member is a scattering type liquid crystal display device. In this way, by increasing the numerical aperture after allowing substantially parallel light to enter the liquid crystal display element and passing through the liquid crystal display element, it is possible to widen the viewable range while maintaining the contrast without reducing the illumination efficiency. it can. At this time, by using a scattering type liquid crystal device as a member for increasing the numerical aperture, a dynamic scattering state can be obtained by applying a voltage, so that the transmission state and the scattering state can be electrically controlled. As a result, a desired image can be obtained by setting the transmission state when priority is given to resolution in the viewing angle and resolution that are in a trade-off relationship, and setting the scattering state when widening the viewing angle.
[0044]
Further, by forming a transparent electrode for applying a voltage signal into a matrix, the degree of scattering, that is, the numerical aperture can be provided with a gradation.
Also, (2) an illuminating unit that generates a substantially parallel light beam and a light beam incident from the illuminating unit.
A liquid crystal display element that displays an image, and a numerical aperture increasing member that is disposed in the vicinity of the liquid crystal display element on the optical path of the image light beam emitted from the liquid crystal display element and diffuses the image light beam. In the liquid crystal display device, the numerical aperture increasing member is a prism array. In this way, by using an element in which prisms are arranged in a plane as a member for increasing the numerical aperture, it is possible to obtain an effect of increasing the viewing angle while suppressing the cost from the element production surface as compared with a diffraction grating or the like. Further, the viewing angle can be changed according to the apex angle of the prism to be manufactured.
[0045]
(3) An illuminating unit that generates a substantially parallel light beam, a liquid crystal display element that displays an image when the light beam is incident from the illuminating unit, and the liquid crystal on the optical path of the image light beam emitted from the liquid crystal display element A numerical aperture increasing member disposed in the vicinity of the display element for diffusing the image light flux, and the numerical aperture increasing member transmits the luminous flux for each pixel emitted from the liquid crystal display element to the liquid crystal display element side. A plurality of reflecting surfaces for diverging and reflecting and reflecting surfaces for reflecting the divergently reflected light flux in the image display direction are arranged corresponding to the pixel pitch of the liquid crystal display element in a state of being opposed to each other with a predetermined distance. The liquid crystal display element characterized by the above. As described above, as the numerical aperture increasing member, the reflection surface that diverges and reflects the light flux of each pixel emitted from the liquid crystal display element toward the liquid crystal display element and the reflection surface that reflects the divergent reflected light flux in the image display direction. If a plurality of arrangements corresponding to the pixel pitch of the liquid crystal display element are used while being opposed to each other by a predetermined distance, the reflective surface to be diffusely reflected has a curvature, or the distance between the divergent reflective surface and the planar reflective surface By changing, the increase in the numerical aperture can be made as desired. In addition, it is effective to increase the numerical aperture if the divergent reflecting surface is configured to have a convex surface facing the liquid crystal display element.
[0046]
(4) The liquid crystal display device according to (3), wherein the divergent reflection surface further has a function of transmitting light. As described above, the numerical aperture and the intensity of light in the direct viewing direction can be changed by changing the transmittance so that a part of the light is transmitted through the divergent reflection surface. That is, the viewing angle dependency can be changed. (5) An illuminating unit that generates a substantially parallel light beam, a liquid crystal display element that displays an image when the light beam is incident from the illuminating unit, and the liquid crystal on the optical path of the image light beam emitted from the liquid crystal display element A numerical aperture increasing member disposed in the vicinity of the display element for diffusing the image light flux, and the numerical aperture increasing member bundles optical fibers in a direction perpendicular to the length direction into a plate shape Therefore, the liquid crystal display device is characterized in that the reflection boundary surface inside each optical fiber has an uneven shape. With this configuration, the light emitted from the liquid crystal display element is guided in the length direction by each optical fiber. At this time, the light is diffused in the fiber by the unevenness of the reflection boundary surface and emitted from the end of the fiber. As a result, the numerical aperture increases in total. Also, the viewing angle dependency can be reduced.
[0047]
(6) The liquid crystal display device according to (5), wherein the reflection boundary surface of the optical fiber is a concavo-convex surface having a diffractive action. With such a configuration, the light beam propagating in the fiber is diffracted by the diffractive action of the diffractive surface provided on the reflecting surface, and as a result, the numerical aperture is increased based on the diffraction angle and diffraction efficiency when exiting the fiber end. Show. (7) An illuminating unit that generates a substantially parallel light beam, a liquid crystal display element that displays the image by the incident light beam from the illuminating unit, and the liquid crystal display on the optical path of the image light beam emitted from the liquid crystal display element A numerical aperture increasing member disposed in the vicinity of the element for diffusing the image light beam, wherein the numerical aperture increasing member is a diffusion diffraction grating having a grating surface having irregularities for producing a diffusing action. The liquid crystal display device. Originally, in the case of a simple diffraction grating, the light beam is directed only in the direction satisfying the diffraction condition as described above, and the display image can be viewed only in that direction. In addition, due to wavelength dependence, color unevenness appears in the image. In addition, in the case of a simple diffuser, light is diffused by unevenness on the surface of the plate, so there are parts of the unevenness that scatter light in a direction that is easy to enter the observer's eyeball and parts that are difficult to enter As a result, a portion that diffuses light in a direction that easily enters the eyeball appears bright, and a portion that does not look dark appears to be dark. Therefore, by configuring as described above, viewing angle dependency can be reduced by utilizing both diffraction and diffusion actions simultaneously. That is, light is diffused by the diffusing action of the surface irregularities around the direction satisfying the diffraction condition of the diffraction grating, so that the viewing angle is wider than the diffusion plate, and chromatic aberration due to diffraction is weakened. Further, the control of the light spread angle can be easily controlled by the pitch of the diffraction grating as compared with the case of using only a diffusing plate.
[0048]
(8) The diffusion diffraction grating has a diffraction angle of the first-order diffracted light with respect to the 0th-order diffracted light by the grating surface as₁The diffusion angle when the intensity is 50% of the intensity in the direction perpendicular to the surface is θ₂If
[0049]
[Equation 5]
0.3θ₁<Θ₂<0.7θ₁
(7) The liquid crystal display device according to (7) above, wherein the liquid crystal display device has unevenness that generates diffusion that satisfies the above. In this way, the direction other than the direction satisfying the diffraction condition is interpolated by the diffused light, so that the emission light distribution becomes uniform. Here, the diffraction action is weakened as the surface becomes rough. That is, the emission light distribution in the direction satisfying the diffraction condition is weakened.
[0050]
Therefore, if the surface is too rough, it becomes no different from a normal diffusion plate, and the problem of light and shade of the diffusion plate appears strongly. On the other hand, if the surface is not rough, it becomes the same as a normal diffraction grating, and there is a problem that a color peculiar to the diffraction grating appears or light is lost except in a direction satisfying the diffraction condition. Appropriate blending of both diffractive and diffusive phenomena can improve the light and darkness that is likely to occur during diffraction and diffusion alone.
[0051]
(9) an illuminating unit that generates a substantially parallel light beam, and a liquid crystal display element that displays an image by the incident light beam from the illuminating unit;And furtherIt is disposed in the vicinity of the liquid crystal display element on the optical path of the image light beam emitted from the liquid crystal display element, and diffuses the image light beam.At least two numerical aperture increasing surfaces selected from a diffusion plate, a diffraction grating, and a prism arrayA liquid crystal display device comprising the liquid crystal display device. In such a configuration, by combining a plurality of surfaces having different numerical aperture increases, it is possible to increase the viewing angle and make the diffusion of light within the viewing angle more uniform. As a result, the shading is not seen within the viewing angle.
[0052]
(10) The liquid crystal display device according to (9), wherein there are two numerical aperture increasing surfaces, one is a diffraction grating surface and the other is a diffusion surface. When only the diffraction grating surface is used, the light beam is directed only in the direction satisfying the diffraction condition, and the display image can be viewed only in that direction. In addition, due to wavelength dependence, color unevenness appears in the image. Moreover, since the light is diffused by the unevenness on the surface of the diffusion surface only with the diffusion surface, there are a portion of the unevenness that scatters light in a direction that easily enters the observer's eyeball and a portion that scatters in a direction that is difficult to enter. As a result, a portion that scatters light in a direction that easily enters the eyeball looks bright, and a portion that does not look dark appears to be dark. Therefore, when the above numerical aperture increasing surfaces are two, one is a diffraction grating surface, and the other is a diffusing surface, that is, by combining surfaces having problems with these single surfaces, the viewing angle dependency can be reduced. . That is, since the light is diffused by the diffusion surface around the direction satisfying the diffraction condition of the diffraction grating surface, the viewing angle is wider than that of the single diffusion surface, and chromatic aberration due to diffraction is weakened.
[0053]
In addition, the diffraction grating surface allows control of the branching direction of the light beam, and can reduce unwanted scattered light that is not efficiently guided to the eyeball. Increases nature.
(11) The pixel pitch of the liquid crystal display element is P, and the diffraction angle of the 1st-order diffracted light with respect to the 0th-order diffracted light by the diffraction surface of the diffraction grating is θ₁  And the diffusion angle at 50% of the intensity of transmitted light in the direction perpendicular to the diffusion surface is θ₂  And the distance from the liquid crystal display element to the diffraction grating is L₁  , The distance from the diffraction grating to the diffusion surface is L₂Then,
[0054]
[Formula 6]
P> L₁Tanθ₁+ L₂Tanθ₂
The liquid crystal display device according to (10), wherein the pixel pitch P satisfies the following condition. With such a configuration, blur due to crosstalk such as blurring to adjacent pixels is eliminated.
[0055]
(12) The liquid crystal display device according to (9), wherein the numerical aperture increasing surface is two, one is a prism array, and the other is a diffusing surface or a diffraction grating.
That is, if the prism array is a single unit, the light beam is directed only in the direction of refraction by each prism, and the display image can be viewed only in that direction. In addition, unevenness of color appears in the image due to chromatic aberration caused by the prism during refraction. In the case of only the diffusion surface, light is diffused by the unevenness on the surface of the diffusion surface, so there are a portion of the unevenness that scatters light in a direction that easily enters the viewer's eyeball and a portion that scatters in a direction that is difficult to enter. As a result, a portion that scatters light in a direction that easily enters the eyeball appears bright, and a portion that does not look dark appears dark. Therefore, by combining the two numerical aperture increasing surfaces, one of which is a prism array and the other of which is a diffusing surface, and combining these alone having problems, the respective problems can be reduced, and as a result, the viewing angle dependency can be reduced. . That is, since the light emitted from the liquid crystal element is diffused by the diffusing surface around the direction refracted by the prism, the viewing angle is wider than the surface of the diffusing surface 1, and the chromatic aberration due to the prism is weakened. If the two numerical aperture increasing surfaces are a prism array and the other is a diffraction grating, the viewing angle increases because the diffraction angle by the diffraction grating surface and the refraction angle of the prism array are combined. The emitted light distribution becomes uniform.
[0056]
(13) The liquid crystal according to (9), wherein there are three numerical aperture increasing surfaces, one is a prism array, the other is a diffraction grating surface, and the other is a diffusion surface. It is a display device. With such a configuration, since the refraction angle of the prism array, the diffraction angle of the diffraction grating surface, and the scattering angle by the diffusion surface are different, the emission light distribution becomes more uniform.
[0057]
(14) The numerical aperture increasing surface includes a plurality of diffusion surfaces, and the diffusion surface arranged on the liquid crystal display element side has the same or larger diffusion angle than the diffusion surface arranged on the eyeball side. (9) A liquid crystal display device. With such a configuration, partial shading is prevented from being seen. Although there is a problem that the shading mentioned as a defect of the diffusing surface can be seen, this phenomenon is remarkable when a light beam having a small numerical aperture is used. As a method for solving this problem, when a plurality of devices having different diffusion characteristics are used as described above, the larger the diffusion angle, the closer to the liquid crystal display element side, and the smaller, the closer to the eyeball side, the closer to the liquid crystal display element. Since the numerical aperture increases on the side, the shading becomes less conspicuous.
[0058]
(15) The liquid crystal display device according to (9), wherein the numerical aperture increasing surface has a plurality of diffusion surfaces formed in layers. In this way, since it is not necessary to configure a plurality of diffusion surfaces using a plurality of diffusion plates, in addition to the above effects, the configuration of the display device itself is simplified. Also, the thickness can be reduced.
(16) At least one or more numerical aperture increasing surfaces are formed by the microlens array disposed in the vicinity of the liquid crystal display element on the optical path of the image light beam emitted from the liquid crystal display element. The liquid crystal display device according to any one of (1) to (15), wherein the liquid crystal display device is disposed in the vicinity of a plane conjugate with the liquid crystal display element. With such a configuration, the numerical aperture increasing surface is not directly disposed on the liquid crystal display element, but the image is relayed once by the lens and disposed at the relayed conjugate image position. Can be improved.
[0059]
(17) The liquid crystal display device according to any one of (1) to (16), an eyepiece optical system that projects an image displayed on the liquid crystal display device on an eyeball of an observer, and the liquid crystal display A head-mounted image display device comprising: a device and head mounting means for positioning the eyepiece optical system in front of an observer's eyeball. With such a display device, by using a video display element with a wide viewing angle, even in a head-mounted video display device with a wide angle of view, it is possible to avoid a reduction in realism due to contrast inversion or deterioration of visibility. In head-mounted video display devices, there are many cases where there are individual differences such as eye width and head size, and the display system is not positioned at the correct position due to bad wearing condition. Cannot maintain good contrast over the entire screen. This is likely to occur when the viewing angle of the liquid crystal display device is small. Therefore, if the liquid crystal display device having a large viewing angle is used, such a phenomenon is less likely to occur. Further, in the design of the eyepiece optical system of the head-mounted image display device, light rays emitted from the periphery of the display element are apt to be inevitably subject to aberrations. However, by using the above liquid crystal display device, the light flux emitted from one pixel is Since it is uniform over a wide range of angles, the degree of freedom in design increases from the viewpoint of aberrations and the like at the design stage.
[0060]
The present invention is not limited to the liquid crystal display device of the type described in the above embodiment, and can be applied to other known liquid crystal display devices.
[0061]
【The invention's effect】
As is apparent from the above description, the present invention has the advantage that the viewing angle can be increased without reducing the display contrast of the liquid crystal display device.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of a liquid crystal display device according to a first embodiment of the present invention.
FIG. 2 is a diagram illustrating an operation state of the scattering type liquid crystal panel in the first embodiment.
FIG. 3 is a schematic configuration diagram of a liquid crystal display device according to a second embodiment of the present invention.
FIG. 4 is a diagram showing a modification of the second embodiment.
FIG. 5 is a diagram for explaining the operation of the prism array in the second embodiment.
FIG. 6 is a diagram for explaining the operation when the prism surface is reversed in the second embodiment.
FIG. 7 is a diagram showing a modification of the second embodiment.
FIG. 8 is a schematic cross-sectional view of a liquid crystal display device according to a third embodiment of the present invention.
FIG. 9 is a diagram showing a modification of the third embodiment.
10 is a perspective view showing two examples of an optical fiber plate used in a liquid crystal display device according to a fourth embodiment of the present invention. FIG.
FIG. 11A is a diagram showing a structure of a general optical fiber, and FIG. 11B is a diagram showing a structure of an optical fiber in the fourth embodiment.
FIG. 12 is a diagram showing the structure of an optical fiber used in a liquid crystal display device according to a fifth embodiment of the present invention.
FIG. 13 is a perspective view showing a numerical aperture increasing member of a liquid crystal display device according to a sixth embodiment of the present invention.
FIG. 14 is a schematic configuration diagram of a liquid crystal display device according to a seventh embodiment of the present invention.
FIG. 15 is a diagram for explaining the action of only the diffusion plate.
FIG. 16 is a diagram for explaining the effect of the diffraction grating alone.
FIG. 17 is a diagram for explaining the operation in the seventh embodiment.
FIG. 18 is a diagram for explaining the operation when the distance between the diffraction grating and the diffusion plate is made larger than in the case of FIG.
FIG. 19 is a diagram for explaining the operation when the arrangement of the diffraction grating and the diffusion plate is reversed.
20 is a diagram for explaining the operation when the distance between the diffraction grating and the diffusion plate is made larger than in the case of FIG.
FIG. 21 is a diagram for explaining the appearance when the distance between the numerical aperture increasing member and the liquid crystal element is increased.
FIG. 22 is a diagram showing a modification of the seventh embodiment.
FIG. 23 is a diagram showing a modification of the seventh embodiment.
FIG. 24 is a diagram showing a modification of the seventh embodiment.
FIG. 25 is a diagram showing a modification of the seventh embodiment.
FIG. 26 is a diagram for explaining a difference in characteristics between the two types of diffusion plates in FIG. 25;
FIG. 27 is a diagram showing a modification of the seventh embodiment.
FIG. 28 is a schematic configuration diagram of a liquid crystal display device according to an eighth embodiment of the present invention.
FIG. 29A is an external view of a video display apparatus according to a ninth embodiment of the present invention, and FIG. 29B is a schematic configuration diagram thereof.
FIG. 30 is a diagram illustrating a viewing angle in a conventional liquid crystal display device.
FIG. 31 is a cross-sectional view showing a configuration of a general liquid crystal panel.
[Explanation of symbols]
1 point light source
2 Collimator lens
3 LCD panel
4 numerical aperture increasing member
31 Prism array
81 mirror
82 half mirror
101 Optical fiber (circular)
102 Optical fiber (square)
141 diffraction grating
142 Diffuser
281 Scattering liquid crystal device

Claims (3)

An illuminating means for generating a substantially parallel light beam, a liquid crystal display element for displaying a picture by entering a light beam from the illuminating means, and an optical path of an image light beam emitted from the liquid crystal display element, in the vicinity of the liquid crystal display element And a numerical aperture increasing member for diffusing the image light flux. The numerical aperture increasing member is a plate formed by bundling optical fibers in a direction perpendicular to the length direction. A liquid crystal display device characterized in that a reflection boundary surface inside an optical fiber has an uneven shape. The liquid crystal display element, comprising: an illuminating unit that generates a substantially parallel light beam; and a liquid crystal display element that displays an image when the light beam is incident from the illuminating unit. A liquid crystal display device comprising at least two or more numerical aperture increasing surfaces selected from a diffusion plate, a diffraction grating, and a prism array for diffusing the image light flux. 3. The liquid crystal display device according to claim 1 or 2, an eyepiece optical system that projects an image displayed on the liquid crystal display device onto an eyeball of an observer, and the liquid crystal display device and the eyepiece optical system that are positioned immediately before the eyeball of the observer. A head-mounted image display device comprising: a head mounting means positioned on the head.

Images