JP3703329B2 - Image display device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an image display device, for example, a head-mounted display in which image information displayed on a reflective liquid crystal display element as a display element is enlarged and observed through an optical element having a properly set free-form surface, It is suitable for a glasses-type display or the like.
[0002]
[Prior art]
Conventionally, for example, by using an optical element provided with an incident surface, a plurality of reflecting surfaces, and an exit surface on the surface of a transparent body, image information displayed on an image display element such as a liquid crystal is observed as an enlarged virtual image. Various head-mounted image observation devices (image display devices), so-called head mounted displays, have been proposed.
[0003]
For example, a configuration of an optical system particularly excellent in miniaturization as such a head mounted display type image observation apparatus is proposed in Japanese Patent Laid-Open Nos. 7-333551, 8-179238, and 8-234137. Has been.
[0004]
On the other hand, in recent years, various reflective liquid crystal display elements have been used as small display devices. In order to use the reflective liquid crystal display element in an image observation apparatus such as a head mounted display, it is necessary to provide an illumination device to illuminate the liquid crystal display element.
[0005]
FIG. 4 and FIG. 5 are schematic views of a main part of a part of an image display device using a conventional reflective liquid crystal display element.
[0006]
In FIG. 4, reference numeral 101 denotes a reflective liquid crystal display element, in which a light beam from a light source (surface light source) 102 is reflected by a beam splitter (half mirror) 103 that is inclined by approximately 45 ° with respect to the display surface of the liquid crystal display element 101. Illuminated with light. When the projector is a projector, the light beam that has been modulated by the liquid crystal display element 101 and transmitted through the half mirror 103 is projected onto a predetermined surface by the projection lens 104 and observed. In the case of a head mounted display, image information displayed on the liquid crystal display element 101 is enlarged and observed through the lens system 104.
[0007]
In FIG. 5, the light beam from the light source 102 is converted into linearly polarized light (for example, P-polarized light) through the polarizing plate 106, and is passed through the polarizing beam splitter 105 inclined by approximately 45 ° with respect to the display surface of the liquid crystal display element 101. The liquid crystal display element 101 is illuminated. A light beam (S-polarized light) that has undergone light modulation by the liquid crystal display element 101 is reflected by the polarization beam splitter 105 and guided to the projection lens or lens system 104.
[0008]
As a result, when the projector is used, the projection lens 104 projects the image onto a predetermined surface for observation. In the case of a head mounted display, image information displayed on the liquid crystal display element 101 is enlarged and observed through the lens system 104.
[0009]
[Problems to be solved by the invention]
Conventionally, in an image observation apparatus such as an HMD, in order to mount the apparatus on the observer's head, it is important to reduce the size and weight of the entire apparatus. Further, it is an important problem that image information displayed on the display means can be observed well.
[0010]
In order to reduce the size of the entire apparatus when a reflective liquid crystal display element is used as the image display apparatus, it is necessary to incorporate an illuminating device for illuminating it into the apparatus.
[0011]
A beam splitter inclined at 45 ° with respect to the liquid crystal surface constituting the illumination optical system shown in FIGS. 4 and 5 is disclosed in JP-A-7-333551, JP-A-8-179238, and JP-A-8-234137. In other words, a surface inclined by about 45 ° must be disposed between the liquid crystal and the optical system or between the optical system and the pupil. For this reason, specifications such as eye relief and angle of view are reduced as compared with the case where a transmissive liquid crystal display device is used.
[0012]
When the beam splitter is a half mirror, the light amount is lost. When the beam splitter is a polarizing beam splitter (PBS), there is a problem that it is difficult to manufacture.
[0013]
The present invention relates to an illumination optical system from a light source unit to a display unit and a display optical system for guiding a light beam from the display unit to an observer's eyeball when observing image information displayed on a display unit such as a liquid crystal display. Accordingly, an object of the present invention is to provide an image observation apparatus capable of observing the image information with good image quality by reducing the loss of light amount while reducing the size of the entire apparatus.
[0014]
In addition, the present invention uses, for example, a reflection type liquid crystal display element as the image display means, for example, an incident surface on which a light beam from the liquid crystal display element is incident, and a decentered curved surface reflection that reflects the light beam incident from the incident surface. When observing image information displayed on a liquid crystal display element using an optical element in which a surface and an exit surface for emitting a light beam from the curved reflecting surface are integrally formed in a display optical system, the liquid crystal display element is illuminated. By appropriately setting the illumination optical system for this in accordance with the characteristics of the display optical system, it is possible to reduce the size of the entire apparatus and to observe the image information displayed on the liquid crystal display element satisfactorily. An object of the present invention is to provide an image display device suitable for the above.
[0015]
[Means for Solving the Problems]
The image display device of the invention of claim 1
A reflective display element and a light beam from the light source means are incident on the display surface of the display means.Has a triangular prism using a total reflection surfaceIn an image display apparatus having an illumination optical system and a display optical system that guides a light beam from the display means to a pupil of an observer and observes image information displayed on the display means, the illumination optical system includes the The luminous flux from the light source meansIt is totally reflected by the total reflection surface of the prismatic prism.The display means guides the display optical system,Having a plurality of optical working surfaces;Light flux from the display meansTheThe total reflection surface of the prismThroughGuided to the viewer,The plurality of optical action surfaces of the display optical system have a symmetric shape in one plane, and when the symmetry surface is a YZ plane, the prism apex angle Pθ of the prism is
(Dy / Ly) · Wy ° <Pθ<40 °
Dy:The display optical system in the YZ planePupil diameter
Ly:The display means in the YZ planeEffective image display size
Wy:Image display device in YZ planeAngle of view
It is characterized by being set to be.
[0016]
The invention of claim 2 is the invention of claim 1,
The angle θ formed by the total reflection surface and the display surface of the display means is,
(Dy / Ly) · Wy ° <θ<40 °
It is characterized by being.
[0018]
  Claim 3The invention ofClaim 1 or 2In the invention, the display optical system has an optical element using a plurality of reflecting surfaces, and a light beam connecting the light source means, the display means, and the respective substantially center positions of the pupil formed by the display optical system is a reference light beam L0. In this case, the reflecting surfaces constituting the optical element are each composed of a surface inclined with respect to the reference light ray L0.
[0019]
  Claim 4The invention ofClaim 3In the invention, at least one optical surface constituting the optical element is formed of a non-rotationally symmetric aspherical surface having a different curvature for each azimuth.
[0020]
  Claim 5The invention ofClaim 4In the invention, one of the non-rotationally symmetric aspherical surfaces has an optical surface that acts as a total reflection surface and a transmission surface.
[0024]
  Claim 6The invention ofClaims 1 to 5In any one of the inventions, the illumination optical system has at least one non-rotationally symmetric curved surface.
[0025]
  Claim 7The invention ofClaims 1 to 6In any one of the inventions, the display means is a ferroelectric liquid crystal display.
[0026]
  Claim 8The invention ofClaims 1 to 7In any one of the inventions, the light source means has a light source that emits three colors of RGB, and the light source means is lit in synchronization with the image display on the display means.
[0027]
  Claim 9The invention ofClaim 8In the invention, the light source is an LED element that emits three colors of RGB.
[0038]
The invention of claim 24 is the invention of claim 23, wherein
The light source is an LED element that emits three colors of RGB.
[0039]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a schematic view of the main part showing the basic configuration of the image display apparatus of the present invention. In the figure, L1 is an optical element that constitutes a part of the display optical system (enlargement optical system), and includes first, second, and third optical action surfaces (plane, curved surface, aspherical surface, rotationally asymmetric surface, etc.). (Hereinafter also referred to as “surface”) Sa, Sb, Sc. Each of the surfaces Sa, Sb, and Sc has a symmetrical shape with respect to one YZ plane (a symmetric plane, which corresponds to the paper plane in this embodiment). Moreover, you may make it have three or more surfaces. S is the desired pupil position of the observer 1.
[0040]
Reference numeral 2 denotes an image display means (display element) composed of a reflective LCD, and reference numeral 2a denotes a display surface (liquid crystal surface). In the image display means 2 of the present invention, as will be described later, a light beam from the illumination optical system LE is incident on the LCD 2 from an oblique direction, reflected and emitted obliquely, and is guided to an enlargement optical system (display optical system). Since it is configured, it is required to have a wide viewing angle characteristic. In order to meet this requirement, for example, ferroelectric liquid crystal (FLC) is used. Further, a TN liquid crystal whose viewing angle characteristics are improved in combination with a phase compensation plate may be used.
[0041]
Reference numeral 3 denotes a light source means. For example, if the LCD 2 is for a single color, it is composed of a light source that emits monochromatic light or white light. If the LCD 2 is for a color, for example, one LED that emits R, G, B colors is 1 The light flux from the light source 31 formed on the chip is condensed by the lens 32 and used as a surface light source by using the diffusion plate 33. The LEDs emitting three colors of R, G, and B are controlled to emit light in synchronization with the display of an image on the reflective LCD 2 to enable color display.
[0042]
LE is an illumination optical system, which includes a lens L3 that condenses the light beam from the light source means 3 via the polarizing plate KN1, and a prismatic prism that guides the light beam that has passed through the lens L3 to the display surface 2a of the LCD 2 ( Optical member) L2. The surfaces Sd and Se constituting the prism L2 also function as a part of the magnifying optical system that guides the light beam from the reflective LCD 2 to the pupil. Further, the angle θ formed by the reflecting surface Sd of the prism L2 and the display surface 2a of the LCD 2 is configured to be less than 45 °. Also, the prism apex angle of the prism L2(An angle formed by the surface Sd and the surface Se)Pθ is
(Dy / Ly) · Wy ° <Pθ <40 °
However, Dy:In YZ planePupil diameter of the display optical system
Ly:In the YZ planeLCD effective display area length
Wy:In the YZ planeAngle of view of display device
It is said.
[0043]
If the upper limit is exceeded, the prism L2 becomes thick, which is not preferable. If the upper limit is exceeded, a part of the illumination light beam is totally reflected even on the surface Se, and vignetting occurs when the observer tries to gaze at the periphery of the image. This may occur and is not preferable.
[0044]
The lens L3 is not limited to a single lens, and may be composed of a plurality of lenses, a concave mirror, or the like. Further, as shown in a numerical example to be described later, the lens L3 and the prism L2 may be joined to form one component.
[0045]
KN1 and KN2 are polarizing plates, which are arranged, for example, so that their polarization axes are substantially orthogonal. The polarizing plates KN1 and KN2 do not necessarily need to be arranged orthogonally, and may be arranged appropriately according to design conditions such as the optical rotatory power and display mode of the LCD2. Further, depending on the type of LCD 2, there may be a case where only one polarizing plate is used immediately before the display surface 2a, and two polarizing plates are not essential. Further, the polarizing plate KN1 may be disposed between the lens L3 and the prism L2.
[0046]
The shape of the third optical action surface Sc in the optical element L1 is an aspherical surface symmetric with respect to the symmetry plane (YZ plane). The shape of the first optical action surface Sa is a spherical surface or an aspherical surface symmetric with respect to the symmetry plane (YZ plane), and is inclined at an angle to totally reflect the light beam refracted by the third optical action surface Sc. It is arranged.
[0047]
The second optical action surface Sb is a mirror surface (an optical thin film is provided on the surface) made of a concave aspherical surface which is strong as a whole with respect to the symmetry plane (YZ plane), and the first optical action surface. It is arranged to be inclined with respect to the light beam totally reflected in one area of Sa. The light beam reflected by the second optical action surface Sb passes through the first optical action surface Sa and reaches the pupil S.
[0048]
The light constituting the magnifying optical system is defined as a reference ray L0, which is a light beam connecting substantially the center positions of the pupils formed by the light source means 3, the image display means 2 and the magnifying optical system (display optical system) L1. Of the surfaces, at least the surfaces Sa and Sb that act as reflecting surfaces are configured as surfaces inclined with respect to the reference light beam L0, and the optical element L1 is thinned in the z-axis direction.
[0049]
Incidentally, in order to correct decentration aberrations due to the fact that the surfaces Sa and Sb having curvatures are inclined with respect to the reference ray L0, the surfaces Sa to Sc are composed of non-rotationally symmetric aspherical shapes having different curvatures for each azimuth. are doing.
[0050]
Next, the optical action in the basic configuration of the present invention shown in FIG. 1 will be described. As shown in FIG. 1, the light flux from the light source 3 is aligned in the polarization direction (for example, S-polarized light) by the polarizing plate KN1, condensed by the lens system L3 constituting the illumination optical system LE, and the incident surface Sf of the prism L2. Further, the light enters the prism L2, is totally reflected by the reflection surface Sd, is emitted from the transmission surface Se, and illuminates the LCD 2 obliquely in the yz plane with respect to the normal line of the display surface 2a of the LCD 2.
[0051]
The light beam modulated (appropriately rotated for each pixel) and reflected according to the image information on the display surface 2a of the LCD 2 is incident on the prism L2 again from the surface Se, and is then transmitted through the surface Sd that acts as a total reflection surface during illumination. Then, the light is emitted from the prism L2 and travels toward the polarizing plate KN2. In the polarizing plate KN2, for example, light from a pixel that has been rotated 90 ° by the LCD 2 and turned into P-polarized light is transmitted, and light from the pixel that has not been rotated by the image display means 2 and remained S-polarized is blocked. Led to. First, the light passes through the third optical action surface Sc, travels toward the first optical action surface Sa, is totally reflected by the surface Sa, travels toward the second optical action surface Sb, and is reflected by the surface Sb to be converged light. Then, it goes again to the first optical action surface Sa, and this time it passes through this surface Sa to form a virtual image of the image displayed by the image display means 2 and reaches the pupil S of the observer 1 to display the liquid crystal to the observer The virtual image of the image information displayed by the means 2 is visually recognized.
[0052]
According to the present invention, the reflection surface Sd of the prism L2 for guiding the illumination light to the LCD 2 as described above is an angle (preferably (Dy / Ly) · Wy) of less than 45 ° with respect to the display surface 2a of the display element 2. The angle between the optical element L1 and the LCD 2 constituting the magnifying optical system is shortened with respect to the conventional system incorporating the 45 ° mirror, and the reflective display device and the same While incorporating a light source for illumination and an illumination optical system, it is possible to achieve a small and thin image display optical system while ensuring a sufficient angle of view and eye relief.
[0053]
Further, according to the present invention, the light from the light source 31 can be obtained by arranging the prism L2 having the surface Sd that functions as a total reflection surface in the illumination optical system and as a transmission surface in the magnification optical system as described above. Is guided to the observer's pupil S without using a half mirror or the like, so that a bright image display optical system with high light utilization efficiency can be provided.
[0054]
Further, in the basic configuration of the present invention shown in FIG. 1, the surface Sb of the optical element L1 is a half mirror surface as shown in FIG. 6, the prism PZ is joined by the surface Sb, the image displayed on the display means 2, and the external environment The light beam from the image may be guided to the observer's pupil S through the prism PZ and the optical element L1, and both images may be observed in the same field of view. In FIG. 6, an observation system for observing an image of the outside world is configured by an optical system including the surface PZa, the surface Sb, and the surface Sa.
[0055]
The configuration of the embodiment based on the present invention will be described below.
[0056]
[Embodiment 1]
FIG. 2 is a main part configuration diagram of Embodiment 1 of the present invention. In the figure, SS is a pupil formed by the magnifying optical system, L1 is an optical element, and includes first, second and third optical action surfaces (hereinafter also referred to as “surfaces”) S1, which are non-rotationally symmetric aspheric surfaces. S2 and S3. Each surface has a symmetrical shape with respect to one YZ plane (symmetrical plane, which corresponds to the paper plane in this embodiment).
[0057]
Reference numeral 20 denotes a reflective LCD, S9 denotes a display surface of the reflective LCD 20, and S8 denotes a cover glass surface of the LCD.
[0058]
LE1 is an illumination optical system in which a triangular prism prism L21 as an optical member and a plano-convex lens L31 are joined. S6 is an optical action surface that acts as a reflection surface as an illumination optical system, and acts as a transmission surface as an enlargement optical system. A reflection film is formed on a part of the illumination optical system. The illumination light beam is configured to totally reflect. S7 is a surface that acts as a transmissive surface in both the illumination optical system and the magnifying optical system, S10 is a transmissive surface obtained by joining the triangular prism L21 and the lens L31, and S11 is a transmissive surface having a positive power constituting the lens L31. is there.
[0059]
Reference numeral 30 denotes a surface light source, and a light emitting element and an optical system arranged on the back surface of the diffusion plate described in the basic configuration of the present invention to form a surface light source, or a light emission disposed on a side surface such as a known liquid crystal backlight. A surface-emitting light source such as an element formed with an element and a light guide plate, or an EL element can be used as appropriate. When performing color display, an element having a mechanism for emitting R, G, B light is used, and the light emission of the element is performed so that the R, G, B light emission in the element and the R, G, B display in the LCD 20 are synchronized. Can be controlled. SI is a light emitting surface (or a diffusing surface) of the surface light source 30.
[0060]
KN1 and KN2 are polarizing plates arranged so that their polarization axes are substantially orthogonal to each other. The polarizing plate KN1 has optical action surfaces S12 and S13, and the polarizing plate KN2 has optical action surfaces S4 and S5.
[0061]
The aspherical shape of each optical action surface S1 to S3 of the optical element L1 in the present embodiment is expressed using the following equation.
z: = (1 / R) * (x²+ y²) / (1+ (1- (1 + C1) * (1 / R)²* (x²+ y²))^(1/2)) + C2 + C4 * y + C5 * (x²-y²) + C6 * (-1 + 2 * x²+ 2 * y²) + C10 * (-2 * y + 3 * x²* y + 3 * y^Three) + C11 * (3 * x²* y-y^Three) + C12 * (x^Four-6 * x²* y²+ y^Four) + C13 * (-3 * x²+ 4 * x^Four+ 3 * y²-4 * y^Four) + C14 * (1-6 * x²+ 6 * x^Four-6 * y²+ 12 * x²* y²+ 6 * y^Four) + C20 * (3 * y-12 * x²* y + 10 * x^Four* y-12 * y^Three+ 20 * x²* y^Three+ 10 * y^Five) + C21 * (-12 * x²* y + 15 * x^Four* y + 4 * y^Three+ 10 * x²* y^Three-5 * y^Five) + C22 * (5 * x^Four* y-10 * x²* y^Three+ y^Five) + C23 * (x⁶-15 * x^Four* y²+ 15 * x²* y^Four-y⁶) + C24 * (-5 * x^Four+ 6 * x⁶+ 30 * x²* y²-30 * x^Four* y²-5 * y^Four-30 * x²* y^Four+ 6 * y⁶) + C25 * (6 * x²-20 * x^Four+ 15 * x⁶-6 * y²+ 15 * x^Four* y²+ 20 * y^Four-15 * x²* y^Four-15 * y⁶) + C26 * (-1 + 12 * x²-30 * x^Four+ 20 * x⁶+ 12 * y²-60 * x²* y²+ 60 * x^Four* y²-30 * y^Four+ 60 * x²* y^Four+ 20 * y⁶)
The optical system data of this embodiment is shown below. The data defines a coordinate system having the center of the pupil plane SS of the optical element L1 as the origin (0, 0, 0) and the optical axis in the z-axis direction shown in the figure, and defines each surface with respect to the reference coordinate system. The y-coordinate, z-coordinate, and rotation about the x-axis (unit: degree) with the counterclockwise direction on the paper as a positive direction are represented by Y, Z, and A, respectively (x The coordinates and the amount of rotation about the y and z axes are always 0).
[0062]
In the table, R represents the radius of curvature of the surface, and Nd and Vd represent the refractive index and the Abbe number after the surface. It should be noted that when the light beam passes through the same surface, the direction in which the medium is not air is described, and when the light beam is used as a reflecting surface, this is not described.
[0063]
Those including aspherical coefficients C1, C2,... Represent aspherical surfaces according to the aspherical formula defined in this embodiment, those describing Rx represent toric surfaces, surfaces without these instructions represent spherical surfaces, The non-designated coefficient is 0 on the surface with the spherical coefficient designation.
[0064]
Y Z A
SS 0.000 0.000 0.00
R: ∞
S1 -21.055 22.714 -4.90
R: -286.387 Nd: 1.5709 Vd: 33.8
C1: 5.6951E + 01 C5: 1.2624E-03 C6: -1.0259E-05
C10: -1.0063E-05 C11: -1.1861E-04 C12: -1.2583E-06
C13: -8.1437E-08 C14: -1.5282E-07 C20: -3.6312E-09
C21: -6.6657E-09 C22: -1.2994E-08 C23: -1.8270E-10
C24: 3.2026E-11 C25: -3.3331E-11 C26: 1.7955E-11
S2 -7.684 25.621 -34.58
R: -60.499
FFS:
C1: 2.9063E + 00 C5: -1.8798E-03 C6: -1.5350E-03
C10: -2.1037E-05 C11: -4.2092E-05 C12: -1.4078E-06
C13: -8.7082E-07 C14: 4.9603E-07 C20: -1.7039E-08
C21: -6.7412E-09 C22: 2.8031E-08 C23: 4.2253E-10
C24: -1.2736E-10 C25: 2.2765E-10 C26: 8.1350E-11
S3 13.586 29.712 57.62
R: ∞ 0.000000
UDS:
C1: -1.0721E-13 C5: 3.4255E-03 C6: -6.4961E-03
C10: 1.0928E-03 C11: -1.0503E-03 C12: -3.8101E-06
C13: -1.3683E-06 C14: 4.6612E-06 C20: -7.4127E-06
C21: 7.8218E-06 C22: -7.1810E-06 C23: -1.2202E-07
C24: 5.3625E-08 C25: -1.3562E-07 C26: 1.6849E-08
S4 13.083 31.875 60.21
R: ∞
S5 13.257 31.974 60.21
R: ∞
S6 13.604 32.173 60.21
R: ∞ Nd: 1.5163 Vd: 64.1
S7 15.140 33.052 29.82
R: ∞
S8 15.463 33.616 29.82
R: ∞ Nd: 1.5740 Vd: 55.0
S9 15.798 34.201 29.82
R: ∞
S10 25.650 27.285 112.08
R: ∞ Nd: 1.6968 Vd: 55.5
S11 25.933 21.066 112.08
R: -10.806
S12 28.713 19.939 112.08
R: ∞ Nd: 1.4900 Vd: 50.0
S13 28.898 19.863 112.08
R: ∞
SI 29.825 19.487 112.08
R: ∞
In the YZ planePupil diameter Dy: 6.00
In the YZ planeLCD screen size Ly: 6.32
In the YZ planeAngle of view Wy: 21.2 °
Angle θ between surface S6 and surface S9: 30.39 °
Prism L21 apex angle Pθ: 30.39 °
(Dy / Ly) ・ Wy ° = 20.13 °
∴ (Dy / Ly) ・ Wy ° <θ <40 °
(Dy / Ly) ・ Wy ° <Pθ <40 °
Next, the optical action in this embodiment will be described. As shown in FIG. 2, in the light beam from the light emitting surface SI of the surface light source 30, only the linearly polarized light component in a specific direction passes through the surfaces S13 and S12 of the polarizing plate KN1. The transmitted light beam of the linearly polarized light component is refracted and collected by the convex surface S11, transmitted through the surface S10, partially reflected by the reflective film of the surface S6, and the rest is totally reflected and transmitted through the surface S7 toward the LCD 20. Then, the light reaches the image display surface S9 through the cover glass surface S8 and illuminates the reflective LCD 20.
[0065]
The light beam modulated / reflected by the LCD 20 passes through the cover glass surface S8 and the surfaces S7 and S6 of the triangular prism L21, and has a polarization component orthogonal to the polarization axis of the polarizing plate KN1 according to the degree of modulation by the polarizing plate KN2. Only light passes through the surfaces S5 and S4 of the polarizing plate KN2. The transmitted light passes through the third optical action surface S3 of the optical element L1 and travels toward the first optical action surface S1, and is totally reflected by the surface S1 toward the second optical action surface S2. The reflected light is reflected at S2 and becomes convergent light, and again travels toward the first optical action surface S1. This time, it passes through this surface S1 and forms a virtual image of the image displayed on the display element 20 and also forms a pupil SS. .
[0066]
In the present embodiment, a part of the illumination light is reflected on the surface S6 of the prism L21 and the rest is totally reflected. Therefore, it is possible to loosen the design constraint conditions and increase the degree of freedom in design. Further, if the illumination system is configured by joining the prism L21 and the lens L31 as in the present embodiment, there is an advantage that the number of steps during assembly can be reduced.
[0067]
[Embodiment 2]
FIG. 3 is a main part configuration diagram of Embodiment 2 of the present invention. In the figure, SS is a pupil formed by the magnifying optical system, L1 is an optical element, and includes first, second and third optical action surfaces (hereinafter also referred to as “surfaces”) S1, which are non-rotationally symmetric aspheric surfaces. S2 and S3. Each surface has a symmetrical shape with respect to one YZ plane (symmetrical plane, which corresponds to the paper plane in this embodiment).
[0068]
Reference numeral 20 denotes a reflective LCD, S9 denotes a display surface of the reflective LCD 20, and S8 denotes a cover glass surface of the LCD.
[0069]
LE2 is an illumination optical system, and is configured by joining a prism (optical member) L22 and a lens L32. S6 is a curved surface that acts as a reflecting surface as an illumination optical system, and functions as a transmission surface as an magnifying optical system. A reflecting film is formed on a part thereof, and an illumination light beam from a light source is formed on other parts. It is configured to totally reflect. S7 is a surface acting as a transmission surface in both the illumination optical system and the magnifying optical system, S10 is a transmission surface obtained by joining the prism L22 and the lens L32, and S11 is a toric surface shape having a positive power constituting the lens L32. It is a transmission surface.
[0070]
Reference numeral 30 denotes a surface light source, and a light emitting element and an optical system arranged on the back surface of the diffusion plate described in the basic configuration of the present invention to form a surface light source, or a light emission disposed on a side surface such as a known liquid crystal backlight. A surface-emitting light source such as an element formed with an element and a light guide plate, or an EL element can be used as appropriate. When performing color display, an element having a mechanism for emitting R, G, B light is used, and the light emission of the element is performed so that the R, G, B light emission in the element and the R, G, B display in the LCD 20 are synchronized. Can be controlled. SI is a light emitting surface (or a diffusing surface) of the surface light source 30.
[0071]
KN1 and KN2 are polarizing plates arranged so that their polarization axes are substantially orthogonal to each other. The polarizing plate KN1 has optical action surfaces S12 and S13, and the polarizing plate KN2 has optical action surfaces S4 and S5.
[0072]
The aspherical shape of each optical action surface S1 to S3 of the optical element L1 in the present embodiment is expressed using the following equation.
z: = 1/2 * (1 / a + 1 / b) * (y²* cos (w)²+ x²) / cos (w) / (1 + 1/2 * (1 / a-1 / b) * y * sin (w) + (1+ (1 / a-1 / b) * y * sin (w) -(1 / a / b + 1/4 * tan (w)²* (1 / a + 1 / b)²) * x²)^(1/2)) + C20 * x²+ C11 * x * y + C02 * y²+ C30 * x^Three+ C21 * x²* y + C12 * x * y²+ C03 * y^Three+ C40 * x^Four+ C31 * x^Three* y + C22 * x²* y²+ C13 * x * y^Three+ C04 * y^Four+ ...
The optical system data of this embodiment is shown below. The rules for data description are the same as those in the first embodiment.
[0073]
Y Z A
SS 0.000 0.000 0.00
R: ∞
S1 0.705 22.097 2.03
R: ∞ Nd: 1.5709 Vd: 33.8
a: -1.6001E-03 b: -2.0700E-03 w: 7.6561E + 01
C02: -1.2865E-03 C03: 3.1005E-04 C04: -1.7122E-05
C05: 6.5409E-07 C06: -9.2795E-08 C20: -5.2450E-03
C21: 3.0453E-05 C22: -3.9978E-05 C23: 4.3388E-07
C24: 1.9170E-08 C40: -7.5988E-06 C41: -1.9544E-06
C42: -7.0198E-08 C60: -3.0370E-08
S2 0.016 28.019 -24.09
R: ∞
a: -2.1136E-02 b: -2.5257E-02 w: -3.1945E + 01
C02: -2.8889E-04 C03: -1.4933E-04 C04: -5.6307E-06
C05: 1.2648E-06 C06: -9.4413E-08 C20: -1.8636E-03
C21: -3.3320E-05 C22: -7.9416E-06 C23: 8.7542E-07
C24: -7.7610E-08 C40: -2.9596E-06 C41: -3.8702E-07
C42: -4.5477E-09 C60: -1.0830E-08
S3 13.307 26.240 57.17
R: ∞
a: 5.5954E-04 b: 3.5851E-03 w: -8.4177E + 01
C02: 2.2738E-02 C03: -7.4198E-03 C04: -3.0192E-03
C05: 1.4405E-04 C06: 6.0690E-05 C20: 5.4887E-03
C21: -5.9630E-04 C22: 2.7278E-04 C23: 5.4823E-05
C24: -6.4480E-06 C40: -2.9036E-04 C41: 1.6786E-05
C42: 1.8299E-06 C60: 5.6970E-07
S4 14.147 26.782 68.65
R: ∞ Nd: 1.4900 Vd: 50.0
S5 14.333 26.855 68.65
R: ∞
S6 14.613 26.964 68.65
R: 70.000 Nd: 1.5600 Vd: 61.0
S7 22.441 24.576 38.70
R: ∞
S8 22.848 25.084 38.70
R: ∞ Nd: 1.5740 Vd: 55.0
S9 23.238 25.571 38.70
R: ∞
S10 20.506 22.316 108.65
R: ∞ Nd: 1.6968 Vd: 55.5
S11 22.223 21.640 110.90
R: -62.53018
RX: -11.50000
S12 25.400 20.427 110.90
R: ∞ Nd: 1.4900 Vd: 50.0
S13 25.587 20.356 110.90
R: ∞
SI 26.054 20.177 110.90
In the YZ planePupil diameter Dy: 6.00
In the YZ planeLCD screen size Ly: 6.18
In the YZ planeAngle of view Wy: 21.2 °
Angle θ between surface s6 and surface s9: 29.95 °
(Dy / Ly) ・ Wy ° = 20.58 °
∴ (Dy / Ly) ・ Wy ° <θ <40 °
In the present embodiment, since the surface S6 is formed of a curved surface, the central field angle principal ray (the ray traveling in the Z-axis direction from the pupil center, the reference ray O used in the description of the basic configuration of the present invention). The angle formed between the tangent to the surface S6 at the intersection of the surface S6 and the image display surface S9 is θ.
[0074]
Next, the optical action in this embodiment will be described. As shown in FIG. 3, in the light beam from the light emitting surface SI of the surface light source 30, only the linearly polarized light component in a specific direction is transmitted through the surfaces S13 and S12 of the polarizing plate KN1. The transmitted linearly polarized light component is refracted and condensed on the toric surface S11 at different angles in the x-axis direction and the y-axis direction, is transmitted through the surface S10, part is reflected by the reflective film on the surface S6, and the rest is totally reflected. Then, the light passes through the surface S7 toward the LCD 20, reaches the image display surface S9 through the cover glass surface S8, and illuminates the reflective LCD 20.
[0075]
The light beam modulated and reflected by the LCD 20 is transmitted through the cover glass surface S8 and the surfaces S7 and S6 of the prism L22, and only the light of the polarization component orthogonal to the polarization axis of the polarizing plate KN1 according to the degree of modulation by the polarizing plate KN2. Passes through the surfaces S5 and S4. The transmitted light passes through the third optical action surface S3 of the optical element L1 and travels toward the first optical action surface S1, and is totally reflected by the surface S1 toward the second optical action surface S2. The reflected light is reflected at S2 to become convergent light, and again travels toward the first optical action surface S1, and this time, the virtual image of the image displayed on the display element 20 is transmitted through this surface S1 and the pupil SS is formed.
[0076]
In the present embodiment, the surface S7 of the prism L22 has a convex shape and has a power to appropriately share the power of the curved surface constituting the magnifying optical system, thereby reducing the sensitivity of each surface constituting the optical element L1, Tolerance can be increased. Further, in the present embodiment, the surface S11 constituting the illumination optical system is formed in a toric surface shape having different curvatures in the x and y directions, whereby the principal ray to the liquid crystal display surface in the x direction and the y direction generated in the magnifying optical system. The illumination efficiency is improved by appropriately correcting the difference in incident angle.
[0077]
【The invention's effect】
According to the present invention, when observing image information displayed on a display means such as a liquid crystal display, an illumination optical system from the light source means to the display means and a display for guiding the light flux from the display means to the eyeball of the observer By appropriately setting the configuration of the optical system, it is possible to achieve an image observation apparatus that can reduce the loss of light amount while reducing the size of the entire apparatus and observe the image information with good image quality.
[0078]
In addition, according to the present invention, the surface acting on the illumination optical system as a reflection surface for guiding the illumination light to the reflection type image display means is at an angle of less than 45 ° with respect to the display surface of the reflection type image display means. By configuring, the distance from the optical element constituting the magnifying optical system to the reflection type image display means is shortened with respect to the conventional system incorporating the 45 ° mirror, and the reflection type image display means and the light source for illuminating the reflection type image display means In addition, while incorporating the illumination optical system, it is possible to achieve a small and thin image display device while ensuring a sufficient angle of view and eye relief, and also acts as a total reflection surface in the illumination optical system, In the magnifying optical system, by arranging the prism of the surface that acts as the transmission surface, the light from the light source is guided to the observer's pupil without going through the half mirror, etc. Reach Can be achieved.
[Brief description of the drawings]
FIG. 1 is a main part schematic diagram showing a basic configuration of an image display apparatus of the present invention
FIG. 2 is a schematic view of the main part of Embodiment 1 of the present invention.
FIG. 3 is a schematic diagram of a main part of a second embodiment of the present invention.
FIG. 4 is a schematic diagram of a main part of an image display apparatus using a conventional reflective display device.
FIG. 5 is a schematic diagram of a main part of an image display apparatus using a conventional reflective display device.
FIG. 6 is a schematic diagram of a main part of another embodiment of the image display device of the present invention.
[Explanation of symbols]
1 observer
2 Image display means
2a Display surface
3 Light source
L1 optical element
L2 prism
L3 lens system
LE illumination optical system
KN1 first polarizing plate
KN2 second polarizing plate
S, SS Pupil position

Claims (9)

An illumination optical system having a reflective display element, a triangular prism using a total reflection surface for making the light beam from the light source unit incident on the display surface of the display unit, and the light beam from the display unit to the pupil of the observer And a display optical system for observing image information displayed on the display means. The illumination optical system transmits the light beam from the light source means to the total reflection surface of the triangular prism. The display optical system has a plurality of optical action surfaces, and guides the light flux from the display means to the observer through the total reflection surface of the prism. The plurality of optical action surfaces of the display optical system have a symmetric shape in one plane, and when the symmetry surface is a YZ plane, the prism apex angle Pθ of the prism is
(Dy / Ly) · Wy ° <Pθ <40 °
Dy: pupil diameter of the display optical system in the YZ plane
Ly: Effective image display size of the display means in the YZ plane
Wy: An image display device that is set to have an angle of view of the image display device in the YZ plane. The angle θ formed by the total reflection surface and the display surface of the display means is
(Dy / Ly) · Wy ° <θ <40 °
The image display apparatus according to claim 1, wherein: The display optical system includes an optical element using a plurality of reflecting surfaces, and a light beam that connects approximately the center positions of the light source unit, the display unit, and the pupil formed by the display optical system is used as a reference light beam L0. , reflecting surfaces constituting the optical element, according to claim 1 or 2 of the image display apparatus, characterized in that it is constituted by a plane inclined with respect to the reference ray L0, respectively. The image display device according to claim 3 , wherein at least one optical surface constituting the optical element is formed of a non-rotationally symmetric aspherical surface having a different curvature for each azimuth. 5. The image display apparatus according to claim 4 , wherein one of the non-rotationally symmetric aspheric surfaces has an optical surface that functions as a total reflection surface and a transmission surface. 6. The image display device according to claim 1, wherein the illumination optical system has at least one non-rotationally symmetric curved surface. 7. The image display device according to claim 1, wherein the display means is a ferroelectric liquid crystal display. The image display device according to claim 1 , wherein the light source unit includes a light source that emits three colors of RGB, and the light source unit is turned on in synchronization with image display on the display unit. 9. The image display device according to claim 8 , wherein the light source is an LED element that emits three colors of RGB.

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