JP3885386B2 - Method for manufacturing hologram element - Google Patents

Description

【００３９】
ＨＯＥ素子２の仕様
基準波長 ：５３２ｎｍ
厚み ：８μｍ
屈折率 ：１．５
屈折率変化量：０．０６
【００４０】
ＨＯＥ位相係数
C2 : 5.8025×10^-2 C3 :-1.0457×10^-2 C5 :-1.0112×10^-2
C7 :-1.9464×10^-5 C9 :-6.0607×10^-6 C10: 1.6841×10^-7
C12: 4.9205×10^-7 C14: 3.2034×10^-7 C16: 1.1633×10^-8
C18: 2.5071×10^-8 C20: 1.2672×10^-8 C21:-9.0737×10^-12
C23: 7.9093×10^-11 C25: 1.6319×10^-11 C27:-3.3694×10^-11
C29: 2.6194×10^-12 C31: 5.0358×10^-12 C33: 7.2193×10^-13
C35:-5.1512×10^-13 C36: 1.5692×10^-14 C38:-7.3829×10^-14
C40:-2.9860×10^-13 C42:-1.9909×10^-13 C44:-1.4226×10^-13
C46:-1.8836×10^-15 C48:-7.4871×10^-15 C50:-8.9216×10^-15
C52:-2.2137×10^-15 C54: 2.0010×10^-16 C55: 5.2087×10^-18
C57: 6.8463×10^-17 C59: 2.4471×10^-16 C61: 2.9062×10^-16
C63: 7.4263×10^-17 C65: 7.7253×10^-17
【００４１】

【００４２】

【００４３】

【００４４】
また、図４は、実施例の瞳から無限遠の光線を入射させたときの像点（情報表示手段上）での点像の状態を表している。そして、図５は、実施例の瞳から無限遠の光線を入射させたときの像点（情報表示手段上）での歪曲収差の状態を表している。ここでの実線は計測値、破線は計算値である。図４において、それぞれの点像に付けられた▲１▼，▲２▼，▲３▼…の数字は、図５における歪曲図のグリッド上に付けられた数字と一致しており、それぞれの位置関係を示している。これらの図より、本発明の実施形態においては、歪曲性能，点像性能共に良好である事が分かる。
【００４５】
【発明の効果】
以上説明したように、本発明によれば、比較的大きな画角に渡って表示素子からの情報を瞳に表示する機能を持ち、回折効率が高くて表示が明るく、高性能で且つ部品点数が少なくてコンパクトな、ホログラムを用いた情報表示装置を提供する事ができる。
【図面の簡単な説明】
【図１】本発明の情報表示装置の一実施形態を模式的に示す構成図。
【図２】本実施形態のホログラム製造状態を模式的に示す構成図。
【図３】ホログラム製造光学系の露光状態とＨＯＥ素子の機能の説明図。
【図４】瞳から無限遠の光線を入射させたときの像点での点像。
【図５】瞳から無限遠の光線を入射させたときの像点での歪曲収差。
【図６】バンドパスフィルターの配置の一例を模式的に示す構成図。
【図７】ゴーストが発生する配置例を模式的に示す図。
【図８】１／４λ位相板の配置例を模式的に示す構成図。
【図９】入射ベクトルと射出ベクトルの関係を模式的に示す図。
【符号の説明】
１ 瞳
２ ＨＯＥ素子
３ 情報表示手段
４ 光
５ 光源
６ リフレクター
７ 反射板
８ 拡散板
９ バンドパスフィルター
１０ １／４λ位相板
１１ 第１の点光源
１２ 第２の点光源
１３ 絞り
１４ ホログラム製造光学系
Ｇｒ１ 第１レンズブロック
Ｇｒ２ 第２レンズブロック
Ｇｒ３ 第３レンズブロック
Ｇｒ４ 第４レンズブロック[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an information display device using a hologram, and more particularly to an information display device using a hologram for displaying an image of an information display means on a pupil.
[0002]
[Prior art]
In recent years, head-up displays, head-mounted displays, and the like have been proposed as information display devices using holograms. For example, as described in JP-A-6-273690, there has been proposed a game machine using a hologram combiner that displays a CRT image superimposed on a display using a hologram combiner. As a method of manufacturing the hologram combiner, recording is performed using light interference from a two-point light source.
[0003]
In addition, as described in Japanese Utility Model Publication No. 61-2971, as a helmet mount display, a means for displaying information to an aircraft pilot is specifically presented. Is presented. Further, as described in Japanese Patent Laid-Open No. 5-346508, there has been proposed a method for solving field curvature and distortion at a wide angle of view by using a non-axis optical system for the hologram manufacturing optical system.
[0004]
[Problems to be solved by the invention]
However, in the configuration described in JP-A-6-273690, a configuration of a combiner using a hologram is proposed, but a specific configuration is not shown. In addition, no solution is proposed for field curvature and distortion that are expected to occur at a large angle of view. As a manufacturing method, only the idea of exposure from a two-point light source is presented, and only the function of a spherical mirror or an eccentric spherical mirror can be given to a hologram optical element.
[0005]
Further, in the configuration described in the above Japanese Utility Model Publication No. 61-2971, although a specific configuration corresponding to a relatively large angle of view is shown, there is an emergency between the display element and the hologram combiner. In addition, there is a problem that the entire information display device is increased in size because it is a configuration that requires many optical elements (lenses) and is a re-imaging optical system.
[0006]
Furthermore, in the configuration as described in the above-mentioned Japanese Patent Application Laid-Open No. 5-346508, a decentered optical system is used for both of the two manufacturing light beams, and the manufacturing apparatus becomes complicated and large. There is. Further, there is no solution proposed for improving the diffraction efficiency of the hologram when the manufactured hologram is used as a display observation element.
[0007]
In view of these problems, the present invention has a function of displaying information from a display element on a pupil over a relatively large angle of view, high diffraction efficiency, bright display, high performance and compact hologram element. An object of the present invention is to provide a method for manufacturing a hologram element in an information display apparatus using the above-described information.
[0008]
[Means for Solving the Problems]
In order to achieve the above object, the present invention is used in an information display device having information display means for displaying image information and a hologram optical element that reflects image light from the information display means and projects it onto the pupil. A hologram element manufacturing method, wherein the hologram element is a reflective and volume hologram optical element manufactured by being exposed by interference of light emitted from the first and second point light sources. A state in which light from the first point light source is guided to the hologram optical element through at least two optical elements each decentered with respect to the hologram element, while the second point light source is substantially coincident with the position of the pupil Then, the light from the second point light source is directly guided to the hologram optical element for exposure.
[0009]
Further, the light from the first point light source is guided to the hologram element by an optical element decentered in the same plane.
[0010]
Further, the hologram element is manufactured so as to have power for projecting image light onto a pupil.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a configuration diagram schematically showing an embodiment of an information display device of the present invention. This figure represents the YZ plane, and the direction perpendicular to the paper surface is the X-axis direction. As shown in the figure, an HOE element (hologram optical element) 2 is arranged in front of the observer's pupil 1, and an information display means 3 such as an LCD for displaying image information is arranged below the pupil 1. Yes. At this time, the light 4 as the image light emitted from the information display means 3 is transmitted only in a necessary wavelength region in a band pass filter (not shown). Then, it is reflected by the HOE element 2 and guided to the pupil 1. Instead of using the band pass filter, the information display means 3 may emit light only in a limited wavelength region.
[0012]
As described above, using only the information of the necessary wavelength band is effective when the reflective HOE element as in the present embodiment is used. That is, since such a reflection hologram has high wavelength selectivity and large dispersion, it is a necessary measure for preventing the color shift of the display image caused by this. That is, when the hologram is given power to deflect the light beam in any direction, the deflection angle of the light beam varies greatly depending on the wavelength of the light beam due to the large dispersion of the hologram. The stronger the beam deflection function of the hologram, the more pronounced the difference in the amount of deflection by wavelength. When the light beam has a certain wavelength width, it is observed as a color shift, and the resolution of the display image is significantly impaired. In order to prevent this, it is necessary to limit the wavelength width of the light beam incident on the hologram.
[0013]
The deflection power of the hologram is defined by the fringe spacing on the hologram surface. Here, the fringe interval and the deflection angle and wavelength of the light beam have the following relationship.
λ = dx × (sinθr−sinθ0)
However,
λ: wavelength of incident light
dx: Surface fringe interval of the hologram optical element θr: Light exit angle θ0: Light incident angle
[0014]
Therefore, the change in emission angle (Δθr) when a light beam having a certain wavelength width (Δλ) is incident on a hologram is
sinΔθr = Δλ / dx
The required Δλ can be obtained by determining a predetermined hologram and a desired Δθr.
[0015]
When the hologram has a condensing or diverging power like a lens, the surface fringe of the hologram is not uniform over the entire surface, but changes in a local location. Therefore, the above formula is applied to the entire area of the hologram surface, and Δλ necessary to satisfy the desired Δθr at all local locations is obtained, and the wavelength width is limited by the wavelength width limiting member so that it is equal to or less than Δλ. Just do it.
[0016]
Further, when a non-light emitting element such as an LCD is used as the information display means, it is desirable to dispose a band pass filter between the information display means and the illumination optical system. FIG. 6 is a configuration diagram schematically showing an example of the arrangement. In the figure, 5 is a light source, 6 is provided above it, 6 is a reflector having, for example, a parabolic surface as a reflecting surface, 7 is a reflecting plate arranged so as to cover it from above, and 8 is provided above it. It is a diffusion plate. The above is the illumination optical system. Reference numeral 9 denotes a band-pass filter provided between the information display means 3 and the diffusion plate 8 which forms part of the illumination optical system. Other configurations are the same as those shown in FIG. The configuration after the diffusion plate 8 is referred to as a display observation optical system.
[0017]
In FIG. 6, the light 4 indicated by the one-dot chain line and the broken line emitted from the light source 5 is guided while being reflected by the reflector 6 and the reflection plate 7, and enters the diffusion plate 8. Thereafter, the light is incident on the information display means 3 through the band pass filter 9 and is modulated there to become a display light beam. The display light beam is deflected by the HOE element 2 and guided to the observer's pupil 1. In this example, the band pass filter 9 is disposed on the opposite side of the information display means 3 as viewed from the HOE element 2.
[0018]
FIG. 7 is a diagram schematically illustrating an arrangement example in which a ghost is generated by a bandpass filter. As shown in the figure, in this example, a bandpass filter 9 is provided between the information display means 3 and the HOE element 2. When a bandpass filter composed of an interference film is used as the wavelength width limiting member, light in a desired wavelength range is transmitted, but light in other wavelength ranges is reflected.
[0019]
As shown in the figure, when outside light A hits such a bandpass filter 9 as indicated by an arrow, wavelengths other than the allowable wavelength range are reflected in the same manner as a normal mirror, and this is reflected in the HOE. If the ghost light B is incident on the pupil 1 as indicated by an arrow due to surface reflection of the element 2 or the like, it may become a ghost. In order to reduce this, as shown in FIG. 6, a configuration in which the band-pass filter 9 is arranged on the opposite side of the information display means 3 when viewed from the HOE element 2 is effective.
[0020]
Further, in the configuration as shown in FIG. 6, when an LCD is used as the information display means, a ghost can be further reduced by arranging a 1 / 4λ phase plate between the information display means and the wavelength width limiting member. . FIG. 8 is a configuration diagram schematically showing an example of the arrangement. As shown in the figure, along the optical axis X indicated by the one-dot chain line, a bandpass filter 9 that is a wavelength width limiting member, a 1 / 4λ phase plate 10, and an information display means 3 that is an LCD are arranged from the left. Yes.
[0021]
Now, from the right side of the figure, if the external light A is incident as indicated by the arrow, the external light A transmitted through the information display means 3 becomes, for example, linearly polarized light whose polarization direction is vertical by the action of the LCD. Yes. Then, the light passes through the ¼λ phase plate 10 and becomes circularly polarized light, and is reflected by the bandpass filter 9 as circularly polarized light. When the light passes through the quarter-λ phase plate 10 again, the polarization direction is finally rotated by 90 degrees and becomes linearly polarized light in the horizontal direction, so that it cannot be transmitted through the information display means 3 that is an LCD. Thereby, since the external light A is not emitted again, the external light reflection ghost by the wavelength width limiting member is completely eliminated.
[0022]
By the way, as described above, when the display information in the limited wavelength region is incident on the HOE element, it is diffracted in the direction of the pupil by the diffraction action of the HOE element. Therefore, it is preferable that the wavelength region diffracted by the HOE element coincides with the wavelength region of display information. Furthermore, in order to reduce the influence of chromatic aberration generated in the HOE element, the wavelength region of display information is preferably narrower than the wavelength region diffracted by the HOE element.
[0023]
The HOE element performs a diffraction action so that the information display element displays a good image at infinity or a finite distance when viewed from the pupil position. At this time, the distance between the HOE element and the pupil is preferably 20 mm or more and 200 mm or less. If the distance between the HOE element and the pupil is too large, the larger the viewing angle, the larger the size of the HOE element, which is not preferable. Conversely, if this distance is too small, there is no space for arranging the information display means, which is not preferable. Therefore, in order to arrange the information display means without increasing the size of the apparatus, it is preferable that the distance between the HOE element and the pupil is 40 mm or more and 100 mm or less.
[0024]
On the other hand, when the external information in front of the pupil enters the HOE element, it reaches the pupil as it is, except for the wavelength region diffracted by the HOE element. When the wavelength region diffracted by the HOE element is narrower than the wavelength region incident on the entire pupil, the observer can see the information of the outside world with almost no loss. At this time, the wavelength width of the display information is preferably limited to 2 nm or more and 30 nm or less.
[0025]
If the wavelength width is too narrow, the display from the information display means becomes dark, which is not preferable. Conversely, if the wavelength width is too wide, the performance of the display image from the information display means deteriorates due to the influence of chromatic aberration generated in the HOE element, which is not preferable. As described above, due to the effect of the two actions by the HOE element arranged in front of the pupil, information on the outside world and information on the information display means can be superimposed and observed.
[0026]
FIG. 2 is a configuration diagram schematically showing the hologram manufacturing state of the present embodiment. A coherent light beam emitted from a light source (not shown) is split into two light beams by a beam splitter (not shown). Here, the polarization directions of the two light beams are aligned using a wave plate or the like (not shown). These two light beams are spatially filtered through a spherical wave generating lens (not shown) and a pinhole placed at the focal point thereof, and converted into spherical waves with uniform wavefronts.
[0027]
Here, the 1st and 2nd point light sources 11 and 12 of the figure correspond with the pinhole used for the said spatial filtering, respectively. The light from the second point light source 12 enters the HOE element 2 through the diaphragm 13. The HOE element 2 is supported by a glass substrate 2a. The second point light source 12 is set to substantially coincide with the observer's pupil 1 in the usage state of the information display device shown in FIG. As described above, when the positions of the second point light source 12 and the pupil 1 are substantially matched, the production light in the production state and the observation light in the use state substantially coincide, so that the diffraction efficiency in the use state of the HOE element 2 is obtained. Can be improved the most.
[0028]
Further, between the first point light source 11 and the HOE element 2, the first to fourth lens blocks Gr1 to Gr4 constituting the hologram manufacturing optical system 14 are arranged. These lens blocks are decentered only in the YZ cross section of FIG. That is, these lens blocks are incident on the HOE element 2 in the hologram manufacturing state so that the information on the information display means 3 can be observed as a good image on the pupil 1 when the HOE element 2 is in use. It arrange | positions so that the wave front of the light from the point light source 11 may be controlled.
[0029]
That is, the hologram used in the present invention is a volume hologram exposed by interference of light emitted from the first and second point light sources. Further, as described above, it is preferable that the lens block is decentered in only one plane because it is very easy to design and manufacture. Incidentally, the direction perpendicular to the paper surface of FIG.
[0030]
In addition, when the hologram is in use, the HOE element 2 is used obliquely, so that when the HOE element 2 has power, it becomes a non-axial optical system, and the HOE element 2 only functions as a coaxial lens. Causes asymmetrical distortion (trapezoidal distortion) and asymmetric curvature of field in the inclined direction. Therefore, in order to achieve a compact configuration, it is necessary to give power to the HOE element 2, and an aberration correction capability higher than that of the coaxial lens is required. In order to give the HOE element 2 such a function, the exposure state in the hologram manufacturing optical system 14 becomes a problem.
[0031]
FIG. 3 is an explanatory diagram of the exposure state of the hologram manufacturing optical system and the function of the HOE element. First, as shown in FIG. 5A, when the HOE element 2 is arranged on the same axis as the hologram manufacturing optical system 14 and the light source, and exposed in this state, the HOE element 2 is converted into a coaxial lens (group). It will have equivalent work. Therefore, in this case, it is impossible in principle to correct the asymmetrical aberration in the hologram use state.
[0032]
Next, as shown in FIG. 4B, when the HOE element 2 is exposed in an inclined state, the wavefronts of the two lights from the first and second point light sources 11 and 12 are axially symmetric. However, when the HOE element 2 is in use with the two optical axes a and b, it becomes possible to correct asymmetrical aberrations in the vicinity of the axes. However, since the asymmetrical aberration occurs when it is off-axis, the information display means 3 that can be used in this configuration is limited to one having a very small angle of view.
[0033]
Further, as shown in FIG. 4C, when the HOE element 2 is exposed in a state where the hologram manufacturing optical system 14 is decentered, the light beam transmitted through the decentered lens is not axially symmetric and has a complicated wavefront. Therefore, asymmetrical aberration can be corrected. However, in order to have good image performance and distortion performance at a very large angle of view, a configuration in which a plurality of lens groups are tilted in the hologram manufacturing optical system 14 as shown in FIG. It is preferable that
[0034]
As described above, it is preferable that at least two lens units are arranged eccentrically, because asymmetric distortion and asymmetric field curvature are corrected respectively. If there is one lens group, it will be difficult to construct a good information display device that corrects both.
[0035]
Hereinafter, the configuration of the information display device according to the present invention will be described more specifically with reference to construction data, aberration performance, and the like. The following examples correspond to the above-described embodiments. In the construction of the manufacturing optical system of the example, ri (i = 1, 2, 3...) Represents the radius of curvature of the i-th surface counted from the second point light source side, and di (i = 1, 2, 3...) Indicate the i-th axis upper surface distance (here, the state before eccentricity) counted from the second point light source side. Moreover, the kind of glass material used for the production optical system is BK7.
[0036]
For example, as schematically shown in FIG. 9, in the YZ plane (the X axis is perpendicular to the paper surface), the incident vector (Z, Y, X) to the HOE element 2 does not penetrate as shown by the broken line, When deflecting and exiting as an exit vector (Z ′, Y ′, X ′), the relationship between the incident vector and the exit vector is expressed by the following equation.
Z ′ = Z + (m · λ _O / λ) · (dψ / dx)
Y '= Y + (m · λ O / λ) · (dψ / dy)
X ′ = √ (1-Z ′ ² −Y ′ ² )
However,
m: Order λ _O : Reference wavelength λ: Wavelength.
[0037]
Also,
ψ = C ₁ x + C ₂ y + C ₃ x ² + C ₄ xy +
However,
C _j : HOE phase coefficient j: coefficient number (j = 1, 2, 3, 4,...)
It is. here,
j = {(m + n) ² + m + 3n} / 2
However,
m, n is an index of x, y.
[0038]

[0039]
Specification reference wavelength of HOE element 2: 532 nm
Thickness: 8 μm
Refractive index: 1.5
Refractive index change: 0.06
[0040]
HOE phase coefficient
C2: 5.8025 × 10 ^-2 C3: -1.0457 × 10 ^-2 C5: -1.0112 × 10 ^-2
C7: -1.9464 × 10 ^-5 C9: -6.0607 × 10 ^-6 C10: 1.6841 × 10 ^-7
C12: 4.9205 × 10 ^-7 C14: 3.2034 × 10 ^-7 C16: 1.1633 × 10 ^-8
C18: 2.5071 × 10 ^-8 C20: 1.2672 × 10 ^-8 C21: -9.0737 × 10 ^-12
C23: 7.9093 × 10 ^-11 C25: 1.6319 × 10 ^-11 C27: -3.3694 × 10 ^-11
C29: 2.6194 × 10 ^-12 C31: 5.0358 × 10 ^-12 C33: 7.2193 × 10 ^-13
C35: -5.1512 × 10 ^-13 C36: 1.5692 × 10 ^-14 C38: -7.3829 × 10 ^-14
C40: -2.9860 × 10 ^-13 C42: -1.9909 × 10 ^-13 C44: -1.4226 × 10 ^-13
C46: -1.8836 × 10 ^-15 C48: -7.4871 × 10 ^-15 C50: -8.9216 × 10 ^-15
C52: -2.2137 × 10 ^-15 C54: 2.0010 × 10 ^-16 C55: 5.2087 × 10 ^-18
C57: 6.8463 × 10 ^-17 C59: 2.4471 × 10 ^-16 C61: 2.9062 × 10 ^-16
C63: 7.4263 × 10 ^-17 C65: 7.7253 × 10 ^-17
[0041]

[0042]

[0043]

[0044]
FIG. 4 shows the state of a point image at an image point (on the information display means) when an infinite ray is incident from the pupil of the embodiment. FIG. 5 shows the state of distortion at the image point (on the information display means) when a light beam at infinity is incident from the pupil of the embodiment. The solid line here is the measured value, and the broken line is the calculated value. In FIG. 4, the numbers {circle around (1)}, {circle around (2)}, {circle around (3)} attached to the respective point images coincide with the numbers attached on the distortion diagram grid in FIG. Showing the relationship. From these figures, it can be seen that both the distortion performance and the point image performance are good in the embodiment of the present invention.
[0045]
【The invention's effect】
As described above, according to the present invention, the information from the display element is displayed on the pupil over a relatively large angle of view, the diffraction efficiency is high, the display is bright, the performance is high, and the number of components is high. A small and compact information display device using a hologram can be provided.
[Brief description of the drawings]
FIG. 1 is a configuration diagram schematically showing an embodiment of an information display device of the present invention.
FIG. 2 is a configuration diagram schematically showing a hologram manufacturing state of the present embodiment.
FIG. 3 is an explanatory diagram of the exposure state of the hologram manufacturing optical system and the function of the HOE element.
FIG. 4 is a point image at an image point when an infinite ray is incident from a pupil.
FIG. 5 shows distortion aberration at an image point when an infinite ray enters from the pupil.
FIG. 6 is a configuration diagram schematically showing an example of arrangement of bandpass filters.
FIG. 7 is a diagram schematically illustrating an arrangement example in which a ghost is generated.
FIG. 8 is a configuration diagram schematically showing an arrangement example of a quarter-λ phase plate.
FIG. 9 is a diagram schematically showing a relationship between an incident vector and an emission vector.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Pupil 2 HOE element 3 Information display means 4 Light 5 Light source 6 Reflector 7 Reflector 8 Diffuser 9 Band pass filter 10 1 / 4λ phase plate 11 First point light source 12 Second point light source 13 Aperture 14 Hologram manufacturing optical system Gr1 First lens block Gr2 Second lens block Gr3 Third lens block Gr4 Fourth lens block

Claims (3)

A method for manufacturing a hologram element used in an information display device comprising: information display means for displaying image information; and a hologram optical element for reflecting image light from the information display means and projecting it onto a pupil,
  The hologram element is a reflective and volume hologram optical element manufactured by being exposed by interference of light emitted from the first and second point light sources,
  In the exposure, the light from the first point light source is guided to the hologram optical element through at least two optical elements that are decentered with respect to the hologram element, while the second point light source is substantially the position of the pupil. A method for producing a hologram optical element, comprising exposing the light from a second point light source directly guided to the hologram optical element in a matched state. 2. The method of manufacturing a hologram element according to claim 1, wherein light from the first point light source is guided to the hologram element by an optical element decentered in the same plane. 3. The method of manufacturing a hologram element according to claim 1, wherein the hologram element is manufactured to have power for projecting image light onto a pupil.

Images