JP3492277B2 - Polarized illumination device - Google Patents

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention includes an optical element.
Polarized lighting device .

[0002]

2. Description of the Related Art As an optical element (polarization conversion element) for converting light having a random polarization direction into light having a unidirectional polarization direction, the one described in JP-A-7-294906 is known. ing. FIG. 1 (A) is a plan view of such an optical element, and FIG. 1 (B) is a perspective view thereof. This optical element includes a polarization beam splitter array 22 in which a linear polarization beam splitter 30 having a polarization separation film 36 and a linear prism 40 having a reflection film 46 are alternately laminated. Further, the λ / 2 phase difference plate 2 is provided on a part of the exit surface of the polarization beam splitter array 22.
4 are selectively provided.

The linear polarization beam splitter 30 includes two right-angle prisms 32 and 34 and these right-angle prisms 3.
Polarization separation film 3 formed on the boundary surface which is the slope of 2, 34
6 and 6. In manufacturing the polarization beam splitter 30, the polarization separation film 36 is formed on the inclined surface of one of the right-angle prisms, and then the two right-angle prisms 32 and 34 are formed.
Are bonded with an optical adhesive.

The linear prism 40 has two right-angle prisms 42 and 44, and a reflection film 46 formed on the boundary surface which is a slope of these right-angle prisms 42 and 44. In manufacturing the prism 40, the reflection film 46 is formed on the slope of one of the right-angled prisms, and then the two right-angled prisms 42 and 44 are bonded with an optical adhesive. The reflective film 46 is formed of a metal film such as an aluminum film.

The polarization beam splitter array 22 is formed by alternately bonding the plurality of linear polarization beam splitters 30 thus prepared and the plurality of linear prisms 40 with an optical adhesive. Then, the λ / 2 retardation plate 24 is selectively attached to the emission surface of the polarization beam splitter 30.

Incident light containing an s-polarized component and a p-polarized component is incident from the light incident surface. This incident light is first separated into s-polarized light and p-polarized light by the polarization separation film 36.
The s-polarized light is reflected almost vertically by the polarization separation film 36, further vertically reflected by the reflection film 46, and emitted from the prism 40. On the other hand, the p-polarized light passes through the polarization separation film 36 as it is, and the
It is converted into polarized light and emitted. Therefore, all the light fluxes having random polarization directions incident on this optical element are s
It is emitted as a polarized light beam.

[0007]

In the conventional optical element shown in FIG. 1, four right angle prisms 32, 34, 42, 44 are provided.
Are each bonded with an optical adhesive. Therefore,
The s-polarized light and the p-polarized light must pass through the optical adhesive layer formed at the boundary of the prism many times between the time when the light is incident on the optical element and the time when the light is emitted. Since the optical adhesive layer absorbs light to some extent, the intensity of light decreases each time it passes through the optical adhesive layer. As a result, there has been a problem that the light use efficiency is considerably reduced.

The present invention has been made to solve the above-mentioned problems in the prior art, and an object of the present invention is to provide a technique capable of increasing the utilization efficiency of light in an optical element.

[0009]

In order to solve at least a part of the above-mentioned problems, the device according to the present invention divides light from a light source into a plurality of intermediate light beams, and the plurality of intermediate light beams. Each of which is separated into two types of polarized light by an optical element, and then converted into one type of polarized light by a polarization conversion means, wherein the optical element includes a light incident surface and the light incident surface. A first and a second film forming surface which are parallel to each other and are formed so as to form a predetermined angle with the light incident surface and the light emitting surface, and the first film forming surface. Insert an optical adhesive layer on the film formation surface.
On the second film formation surface and the polarization separation film formed without
A plurality of first translucent members each including a reflective film formed without an optical adhesive layer, and an optical adhesive
Bonded alternately with the plurality of first light-transmitting member Te,
A plurality of second translucent members each having a light incident surface and a light exit surface formed on the same plane as the light incident surface and the light exit surface of the plurality of first translucent members, respectively. It is characterized by

According to the present invention , of the light incident from the light incident surface of the first translucent member, the polarization component reflected by the polarization separation film does not pass through the layer of the optical adhesive and the reflection film. And then exits from the polarization beam splitter. Therefore, it is possible to reduce the number of times that the polarized component passes through the layer of the optical adhesive, and thus it is possible to improve the light utilization efficiency.

In the above invention , it is preferable that the reflection film is formed of a dielectric multilayer film.

The reflection film formed of the dielectric multilayer film can increase the reflectance of a specific linearly polarized light component as compared with a metal reflection film such as an aluminum film. Therefore, it is possible to further improve the light utilization efficiency.

[0013]

[0014]

In the above invention , it is preferable that the second light transmitting member further comprises a light shielding means provided corresponding to the light incident surface of the second light transmissive member.

If light is incident from the light incident surface of the second light transmissive member, this light is reflected by the reflection film and then,
It passes through the optical adhesive layer many times while being separated into s-polarized light and p-polarized light by the polarization separation film. Therefore, if such light is blocked by providing a light blocking means corresponding to the light incident surface of the second light transmissive member, the light entering the optical element can pass through the optical adhesive layer many times. Can be prevented.

Further, in the above invention , the first and second
Adhesive layers are provided on the boundary surfaces between the light-transmissive members, and the first and second transmissive films are arranged so that the distance between the polarization separation film and the reflection film is substantially equal through the optical element. It is preferable that at least a part of the thickness of the optical member and the thickness of the adhesive layer is set.

With this arrangement, the distance between the polarization separation film and the reflection film becomes equal, so that the positional accuracy of the film in the optical element is improved and the light utilization efficiency is improved.

Further, in the above invention , it is preferable that the thickness of the second light transmissive member is set smaller than the thickness of the first light transmissive member. This makes it possible to equalize the distance between the polarization separation film and the reflection film and improve the light utilization efficiency of the optical element.

The thickness of the second translucent member is equal to that of the first translucent member.
It is preferably in the range of about 80% to about 90% of the thickness of the translucent member.

Further, the thickness of the first light-transmissive member may be approximately equal to the value of the thickness of the second light-transmissive member plus twice the thickness of the adhesive layer. preferable.

A plurality of optical elements are provided on the light incident surface side of the optical element.
It is preferable that the small lenses are provided, and that the mutual intervals of the plurality of polarization separation films in the optical element are set to substantially correspond to the pitch of the plurality of small lenses.

In this case, the plurality of light beams emitted from the plurality of small lenses can be configured to enter the corresponding polarization separation films, so that the light utilization efficiency is improved.

As an example, an adhesive layer is provided on a boundary surface between the first and second light-transmissive members, and the plurality of polarization separation films are spaced apart from each other by the plurality of small lenses. At least a part of the thickness of the first and second translucent members and the thickness of the adhesive layer is set so as to substantially correspond to the pitch of the lens optical axis.

Alternatively, the plurality of small lenses have a plurality of different lens optical axis pitches, and the mutual spacings of the plurality of polarization separation films substantially correspond to the plurality of different lens optical axis pitches. It is preferable that at least a part of the thicknesses of the first and second translucent members and the thickness of the adhesive layer is set.

In this way, even if the pitches of the optical axes of the lenses are different, the light beams emitted from the respective small lenses can be made to enter the corresponding polarization separation films, so that the light utilization efficiency can be improved. Is improved.

Further, in the above invention , the optical element
A plurality of small lenses are provided on the light incident surface side, and the mutual intervals of the plurality of polarization separation films in the optical element substantially correspond to the pitch of the plurality of light beams emitted from the plurality of small lenses. Is preferably set to.

The pitch of the luminous flux emitted from the small lens is
It does not always match the pitch of the lens optical axis.
Even in such a case, the light flux emitted from each small lens can be configured to enter the corresponding polarization separation film, so that the light utilization efficiency is improved.

As an example, an adhesive layer is provided on a boundary surface between the first and second light-transmissive members, and the plurality of polarization separation films are spaced apart from each other by the plurality of small lenses. In order to almost correspond to the pitch of a plurality of emitted light flux,
At least a part of the thicknesses of the first and second translucent members and the thickness of the adhesive layer is set.

Further , in any one of the constitutions of the above inventions,
The polarized light on at least one end of the optical element.
Dummy area where neither separation surface nor reflection surface exists
However, it may be formed of a translucent member.

[0031]

[0032]

[0033]

[0034]

[0035]

[0036]

[0037]

[0038]

[0039]

[0040]

[0041]

[0042]

[0043]

[0044]

BEST MODE FOR CARRYING OUT THE INVENTION A. First Example: Next, an embodiment of the present invention will be described based on examples. 2 and 3
FIG. 4A is a process sectional view showing a main process for manufacturing a polarizing beam splitter array that is a first embodiment of the present invention.

In the step of FIG. 2A, a plurality of plate-shaped first transparent members 321 and a plurality of second transparent members 322 are prepared. The polarization separation film 331 is formed on one surface of the two surfaces (film formation surface) of the first translucent member 321 which are substantially parallel to each other. A reflective film 332 is formed on the other surface. None of these films is formed on the surface of the second translucent member 322.

Plate glass is used as the first and second translucent members 321 and 322. However, it is also possible to use a transparent plate-shaped material other than glass. Further, one of the first and second translucent members may be made of a material having a color different from that of the other. This has the advantage that it is easy to distinguish the two members after the polarization beam splitter array is completed.
For example, one member is made of colorless and transparent plate glass,
The other may be formed of blue and transparent plate glass. The plate glass is preferably polished plate glass or float glass, and particularly preferably polished plate glass.

The polarization separation film 331 is a film having a property of selectively transmitting one of s-polarized light and p-polarized light and selectively reflecting the other. Usually, the polarization separation film 3 is formed by stacking dielectric multilayer films having such properties.
31 is formed.

The reflective film 332 is formed by laminating dielectric multilayer films. Of course, the dielectric multilayer film forming the reflection film 332 has a composition and a structure different from those forming the polarization separation film 331. Reflective film 33
2 is a dielectric multilayer film that selectively reflects only the linearly polarized light component (s-polarized light or p-polarized light) reflected by the polarization separation film 331 and does not reflect other linearly polarized light components. preferable.

The reflection film 332 may be formed by depositing aluminum. When the reflective film 332 is formed of a dielectric multilayer film, it is possible to reflect a specific linearly polarized light component (for example, s-polarized light) with a reflectance of about 98%. On the other hand, the reflectance of the aluminum film is at most about 92%. Therefore, if the reflective film 332 is formed of a dielectric multilayer film, the amount of light emitted from the polarization beam splitter array can be increased. Further, since the dielectric multilayer film absorbs less light than the aluminum film, it also has an advantage of generating less heat. In order to improve the reflectance of a specific linearly polarized light component, the reflection film 3
It suffices to optimize the thickness of each film forming the dielectric multilayer film (normally, a structure in which two types of films are alternately laminated) forming 32 or the film material.

In the step of FIG. 2B, the first and second translucent members 321 and 322 are alternately laminated with an optical adhesive. As a result, the optical adhesive layer 325 is provided between the polarization separation film 331 and the second light transmissive member 322, and
It is formed between the reflective film 332 and the second translucent member 322, respectively. 2 and 3, the thickness of each layer 331, 332, 325 is exaggerated for convenience of illustration. Also, the number of glass sheets to be laminated is omitted.

In the step shown in FIG. 3A, the optical adhesive layer 325 is cured by irradiating the surfaces of the translucent members 321 and 322 which are bonded together with ultraviolet light in a direction substantially perpendicular to the surface. Ultraviolet rays pass through the dielectric multilayer film. In this embodiment, the polarization separation film 331 and the reflection film 332 are each formed of a dielectric multilayer film. Therefore, FIG.
As shown in, by irradiating the surfaces of the translucent members 321 and 322 with ultraviolet rays from a direction substantially perpendicular to the surfaces, the plurality of optical adhesive layers 325 can be simultaneously cured.

On the other hand, when the reflection film 332 is formed by vapor deposition of aluminum, ultraviolet rays are reflected by the aluminum film. Therefore, in this case, as shown by the broken line in FIG. 3 (A), ultraviolet rays are emitted from a direction substantially parallel to the surfaces of the transparent members 321 and 322. At this time, the irradiation efficiency of the optical adhesive layer 325 due to the ultraviolet rays is reduced in the portion opposite to the side where the ultraviolet rays are incident. Therefore, it takes a relatively long time for the optical adhesive layer 325 to cure.
On the other hand, if the reflective film 332 is formed of a dielectric multilayer film, the surface of the translucent members 321 and 322 can be irradiated with ultraviolet light from a direction not parallel to the optical adhesive layer 325 in a relatively short time. Can be cured.

In the step of FIG. 3B, the plurality of translucent members 321 and 322 thus adhered to each other are substantially parallel to the surface at a cutting plane (shown by broken lines in the figure) forming a predetermined angle θ. The optical element block is cut out by cutting the optical element block. The value of θ is preferably about 45 degrees. A polarization beam splitter array can be obtained by polishing the surface (cut surface) of the optical element block thus cut out.

FIG. 4 is a perspective view showing the polarization beam splitter array 320 thus manufactured. As can be seen from this figure, the polarization beam splitter array 320 is
Each of the first and second translucent members 321 and 322 each having a columnar shape with a parallelogram cross section has a shape in which they are alternately laminated.

FIG. 5A is a plan sectional view showing a polarization conversion element in which a λ / 2 phase difference plate 381 is selectively provided on a part of the emission surface of the polarization beam splitter array 320 according to the embodiment. Further, FIG. 5B is a plan sectional view showing a polarization conversion element of a comparative example. In the polarization conversion element of the example,
Of the emission surface (the surface on the left side in FIG. 5) of the polarization beam splitter array 320, a λ / 2 phase difference plate 381 as polarization direction conversion means is provided on the surface portion of the second light transmissive member 322.
Is pasted.

The structure of the comparative example shown in FIG.
In the configuration of the embodiment (A), a polarization separation film 331,
The only difference is that the positional relationship with the adjacent optical adhesive layer 325 is reversed. When manufacturing the polarization beam splitter array 320a of the comparative example, first, the first
A reflective film 332 is formed on the surface of the transparent member 321 of
On the other hand, the polarization separation film 3 is formed on the surface of the second transparent member 322.
31 is formed. Then, these translucent members 321,
322 are alternately laminated by the optical adhesive layer 325.

Incident light having a random polarization direction including an s-polarized component and a p-polarized component is incident from the incident surface of the polarization conversion element of the embodiment shown in FIG. 5 (A). This incident light is first separated into s-polarized light and p-polarized light by the polarization separation film 331. The s-polarized light is reflected almost vertically by the polarization separation film 331, further reflected by the reflection film 332, and emitted from the emission surface 326. On the other hand, p-polarized light is
The light directly passes through the polarization separation film 331, is converted into s-polarized light by the λ / 2 phase difference plate 381, and is emitted. Therefore, only the s-polarized light is selectively emitted from the polarization conversion element.

If the λ / 2 retardation plate 381 is selectively provided on the emission surface of the first light-transmissive member 321, only the p-polarized light is selectively emitted from the polarization conversion element. You can

In the polarization beam splitter array 320 of the embodiment shown in FIG. 5A, the p-polarized light transmitted through the polarization separation film 331 is an optical adhesive layer between the incident surface and the emission surface of the polarization beam splitter array 320. Pass 325 once. This also applies to the polarization beam splitter array 320a of the comparative example shown in FIG.

In the polarization beam splitter array 320 of the embodiment, the s-polarized light reflected by the polarization separation film 331 is passed through the optical adhesive layer 325 once between the incident surface and the emission surface of the polarization beam splitter array 320. Does not pass. On the other hand, in the polarization beam splitter array 320 a of the comparative example, the s-polarized light has the optical adhesive layer 3 between the incident surface and the emission surface of the polarization beam splitter array 320.
Pass 25 twice. The optical adhesive layer 325 is almost transparent, but has a property of absorbing some light. Therefore, the amount of light decreases each time the light passes through the optical adhesive layer 325. Further, when passing through the optical adhesive layer 325, the polarization direction may slightly change. In the polarization beam splitter array of the example, the number of times the s-polarized light passes through the optical adhesive layer 325 is smaller than that of the comparative example, so that the light utilization efficiency is higher.

By the way, the polarization beam splitter array 320a of the comparative example also has a small number of optical adhesive layers as compared with the conventional polarization beam splitter array 22 shown in FIG. However, in the example shown in FIG. 5A, it can be seen that the light utilization efficiency is higher than that in this comparative example.

FIG. 10 is a sectional view showing the polarization beam splitter array 320 of the embodiment in further enlarged detail. The thicknesses of the polarization separation film 331 and the reflection film 332 are several μm, and the thicknesses t ₃₂₁ and t _{322 of the} translucent members ₃₂₁ and _{322.
Alternatively} , it can be ignored as compared with the thicknesses t _ad1 and t _ad2 of the optical adhesive layer 325. Therefore, in FIG. 10, the polarization separation film 331 is drawn by one broken line, and the reflection film 332 is drawn by one solid line. In addition, as described above, the polarization separation film 331 and the reflection film 332 are formed on both surfaces of the first light transmissive member 321. The thicknesses t _ad1 and t _ad2 of the optical adhesive layer 325 are
It may be set to a different value depending on the layer position,
Normally, the same value is set throughout the polarization beam splitter 320. In the following description, it is _assumed that the thicknesses t _ad1 and t _ad2 of the optical adhesive layer 325 are set to the same value t _ad .

As shown in the lower part of FIG. 10, the thickness t ₃₂₂ of the second transparent member 322 is 2 from the thickness t _{321 of} the first transparent member ₃₂₁ to the thickness t _ad of the optical adhesive layer 325. Equal to the value obtained by subtracting the double. This relationship is the same for the thicknesses (L ₃₂₁ , L ₃₂₂ , _Lad ) when measured in the direction along the light exit surface 326 and the light entrance surface 327 of the polarization beam splitter array 320. For example, the first translucent member 321
If the thickness t ₃₂₁ of the optical adhesive layer 325 is 3.17 mm, the thickness t _ad of the optical adhesive layer 325 is usually about 0.01 to 0.3.
Since it is within the range of mm, the thickness t ₃₂₂ of the second light transmissive member ₃₂₂ is within the range of 3.15 to 2.57 mm. As in this example, the thickness t ₃₂₂ of the second translucent member ₃₂₂ is
About 80% to about 9 of the thickness t ₃₂₁ of the first translucent member 321
It is preferably 0%. As a concrete example,
_{t 321 = 3.17mm, t ad =} 0.06mm, t 322 =
It can be set to 3.05 mm.

As described above, the two kinds of translucent members 321,
By adjusting the thickness of 322 in advance, the distance between the polarization separation film 331 and the reflection film 332 after the attachment can be made substantially uniform over the entire polarization beam splitter array 320.

Actually, the thicknesses t ₃₂₁ and t ₃₂₂ of the transparent members 321 and ₃₂₂ and the thickness t _ad of the optical adhesive layer 325 are used.
Manufacturing error may occur.

FIG. 11 shows the polarization beam splitter array 3
A plurality of small lenses (condensing lenses) 3 on the light incident surface side of 20.
Condensing lens array 31 in which 11 are arranged in a matrix
It is sectional drawing which shows the state which provided 0. On the light incident surface of the polarization beam splitter array 320, the effective incident area EA (the incident surface of the light corresponding to the polarized light separating film 331) where the light that is incident on the polarization separating film 331 and converted into the effective polarized light is incident.
And the invalid incident area UA (the incident surface of the light corresponding to the reflective film 332) on which the light that is incident on the reflective film 332 and is converted into the invalid polarized light is incident. The size Wp of the effective incident area EA and the invalid incident area UA in the x direction is 1 of the size WL of the condenser lens 311 in the x direction.
Equal to / 2. Further, the center (lens optical axis) 311c of the condenser lens 311 is arranged to be equal to the center of the effective incident area EA in the x direction. Effective incident area EA
Is the polarization separation film 331 and the polarization beam splitter 320.
Corresponding to the area projected on the light incident surface of. Therefore, the pitch in the x direction of the polarization separation film 331 is set to be equal to the pitch in the x direction of the lens optical axis 311c of the condenser lens 311.

It should be noted that the condensing lens 311 at the right end of FIG. 11 is not formed with the corresponding polarization separation film 331 or reflection film 332. This is because the amount of light that passes through the condenser lens 311 at the end is relatively small, and therefore the light utilization efficiency is not significantly affected even if these films are not provided.

FIG. 12 shows the pitch of the polarization separation film 331 as
A value different from the pitch of the lens optical axis 311c of the condenser lens 311 is set, and the two polarization beam splitter arrays 320 'are arranged so that the polarization separation film 331 and the reflection film 332 face each other with the system optical axis L as the center. It is explanatory drawing which shows the case where it is made to oppose. In the drawing, the part on the left side of the system optical axis is omitted.

The middle part of FIG. 12 shows a condenser lens array 31.
The light amount distribution of the light condensed by the respective lenses La to Ld of 0 and illuminating the incident surface of the polarization beam splitter array 320 ′ is shown. In general, the light intensity Ia of the light condensed by the lens La closest to the system optical axis (the center of the polarization beam splitter array 320 ′) is the strongest, and the light condensed by the lens farther from the optical axis is weaker, In FIG. 12, the light intensity Id of the light condensed by the fourth lens Ld is the weakest. In addition, the light amount distribution of the light condensed by each of the lenses La to Ld is at a certain lens position (the third lens L in FIG. 12).
With the position (c position) as a boundary, the distribution is closer to the optical axis with respect to the center of the lens, and the distribution is closer to the optical axis with respect to the center of the lens. In FIG. 12, the light amount distribution Pc of the light condensed by the lens Lc is distributed almost in the center of the lens, and the lens L
b, La, and light intensity distributions Pb, Pa closer to the optical axis, the distribution gradually becomes closer to the system optical axis. Further, the light amount distribution Pd of the light condensed by the lens Ld is located on the opposite side of the system optical axis. In such a case, if the center of the effective incident area EA of the polarization beam splitter array 320 ′ is uniformly aligned with the center of the lens optical axis, the light loss due to the deviation of the light amount distribution as described above occurs. Particularly, in the vicinity of the light source optical axis, the deviation between the light amount distribution of the light emitted from the lens array and the effective incident area EA causes a large light loss. Therefore, each effective incident area of the polarization beam splitter array 320 ′ is adjusted according to the distribution of the light emitted from the condenser lens array 310, that is, according to the peak interval of the light amount distribution of the light emitted from the condenser lens array 310. It is preferable to arrange the centers of EA. In other words, the light transmissive member 32 is arranged so that the distance between the polarization separation films 331 matches the distance between the peaks of the light quantity distribution.
1, ₃₂₂ thicknesses t ₃₂₁ and t ₃₂₂ and optical adhesive layer 325
It is preferable to adjust the thickness t _ad (FIG. 10).

In order to use the light condensed by the lens array 310 more effectively, it is preferable that the light condensed by the lens closer to the optical axis be used more effectively. In particular, the amount of light near the optical axis of the light source is large, and
Distribution Pa of light emitted from the lens La near the optical axis of the light source
Is closer to the light source optical axis side than the center optical axis of the lens, so that the center of the effective incident area EA1 closest to the light source optical axis side of the polarization beam splitter array 320 ′ is almost aligned with the peak position of the light distribution Pa. Is preferred.

The configuration shown in FIG. 12 has the condenser lens array 3
The widths of the effective incident areas EA1 to EA4 and the invalid incident areas UA1 to UA4 (that is, the intervals between the polarization separation films 311) are made to correspond to the light intensity and the light amount distribution of the light emitted from each of the condenser lenses 311 of 10. is there. That is, the effective incident area EA of the polarization beam splitter array 320 '(EA in the figure
1 to EA4) and the invalid incident area UA (UA1 to U in the figure)
A4) has a width Wp ′ in the x direction which is equal to that of the condenser lens array 310.
Is larger than 1/2 of the width WL of each lens La to Ld in the x direction.

In the example of FIG. 12, the polarization beam splitter array 320 'is arranged so that the center of the lens Lc in the third column and the center of the corresponding effective incident area EA3 are made equal.
Are arranged. Normally, the width of each invalid incident area UA is
Since the width is equal to the width Wp 'of the effective incident area EA, the two effective incident areas EA2 and EA1 on the left side are gradually closer to the system optical axis with respect to the centers of the lenses Lb and La. The rightmost effective incident area EA4 is located on the opposite side of the system optical axis with respect to the center of the lens Ld. As a result, the effective incident areas EA1 to EA4 substantially coincide with the peak position of the light amount distribution of the light emitted from the condenser lens array 310. In particular, since a predetermined number of lenses close to the optical axis, for example, two to three lenses, have high light intensity, the light quantity distribution of the light condensed by these lenses and the effective incident area corresponding thereto are almost the same. A match is preferred. With such a configuration, it is possible to further improve the light utilization efficiency. It should be noted that the number of lens arrays and each lens are used to determine how much the effective incident area width should be increased with respect to ½ of the lens width and which lens should be arranged with reference to the effective incident area. It can be easily obtained experimentally from the relationship of the light intensity distribution. Further, the widths of the effective incident area and the invalid incident area need not be limited to be larger than 1/2 of the width of the lens, and may be different depending on the actual light quantity distribution for irradiating the light incident surface of the polarization beam splitter array 320 ′. It is determined.

In the examples shown in FIGS. 11 and 12, the small lenses 311 of the condenser lens array 310 are assumed to have the same size, but the small lenses may differ in size depending on the position. FIG. 13 shows a condenser lens array 31 having a plurality of small lenses of different sizes.
It is the top view which shows 0 ', and its BB sectional drawing. Figure 1
In FIG. 3A, the broken line circle indicates a region where the amount of light from the light source is relatively large.

In this condenser lens array 310 ', the first small lenses 312 having a relatively large size are arranged in a matrix around the system optical axis L, and the second small lenses 313 having a relatively small size are arranged. Are arranged in a substantially matrix shape near the end of the condenser lens array 310 ′. In order to achieve the same configuration and effect as those in FIG. 11 for such a condenser lens array 310 ', the center of each effective incident area of the polarization beam splitter array (that is, the pitch of the polarization separation film). But the corresponding small lenses 31
The light-transmissive member 32 so as to match the pitch of 2, 313.
1, ₃₂₂ thicknesses t ₃₂₁ and t ₃₂₂ and optical adhesive layer 325
At least part of the thickness t _ad (FIG. 10) of the is adjusted.
Alternatively, in the case where the same configuration and effect as those in FIG. 12 described above are achieved, the centers of the respective effective incident regions of the polarization beam splitter array (that is, the pitch of the polarization separation film) are arranged from the corresponding small lenses 312 and 313. The translucent member 3 is arranged so as to match the pitch of the light amount distribution of the emitted light flux.
21, ₃₂₂ thicknesses t ₃₂₁ and t ₃₂₂ and the optical adhesive layer 32.
At least a part of the thickness _tad of 5 is adjusted.

B. Second Embodiment: FIG. 14 to FIG.
It is explanatory drawing which shows the manufacturing method of the polarization beam splitter array by 2nd Example. In the second embodiment, as shown in FIG. 14, an assembly jig 400 having a horizontal base 402 and a vertical wall 404 erected on the horizontal base 402 is used.

Also in the second embodiment, as in the first embodiment, the first light-transmissive member 321 (sheet glass on which the film is formed) and the second light-transmissive member shown in FIG. 2A. 322 (a plate glass on which a film is not formed) is prepared. Further, the dummy glass 324 shown in FIG. 14 is also prepared. The dummy glass 324 is a flat plate glass on which a polarization separation film and a reflection film are not formed. The dummy glass 324 is a member provided at the end of the polarization beam splitter, and its thickness can be set to a value different from the thickness of the first and second light transmissive members 321 and 322.

In order to obtain the state shown in FIG. 14, first, the dummy glass 324 is placed on the horizontal table 402, and the photocurable adhesive is applied to the upper surface thereof. And the 1st translucent member 321 is piled up on it. In this way, while the dummy glass 324 and the first translucent member 321 which are stacked via the adhesive layer are slid on each other, the bubbles contained in the adhesive layer are expelled and the thickness of the adhesive layer is made uniform. To In this state, the dummy glass 324 and the first translucent member 321 are in a state of being attracted to each other due to the surface tension. Then, as shown in FIG. 14, the side surfaces of the dummy glass 324 and the first translucent member 321 are connected to the vertical wall 40.
Contact 4 At this time, the dummy glass 324 and the first light-transmissive member 3 are provided on the side surface perpendicular to the contacting side surface.
21 and 21 are shifted by a predetermined shift amount ΔH. Figure 15
Then, ultraviolet rays (denoted as “UV” in the drawing) are irradiated from above the first light-transmissive member 321 to cure the adhesive. The plate material thus bonded is referred to as a "first laminated body". In addition,
It is preferable to irradiate the ultraviolet rays from a direction that is not parallel to the surface of the translucent member 321. By doing so, the adhesive layer can be efficiently irradiated with ultraviolet rays, and the curing time of the adhesive can be shortened. As a result, the throughput of manufacturing the optical element can be improved.

An adhesive is applied to the upper surface of the first laminate, and the second light transmissive member 322 is overlaid (FIG. 16). At this time, the first and second translucent members 32 that are stacked with the adhesive layer interposed therebetween.
While sliding 1 and 322 together, the bubbles contained in the adhesive layer are expelled and the thickness of the adhesive layer is made uniform. Further, the first light transmissive member 321 and the second light transmissive member 322 are displaced by a predetermined shift amount ΔH. In FIG. 17, ultraviolet rays are irradiated from above the second translucent member 321 to cure the adhesive. Thus, the second laminated body is obtained.

Thereafter, in the same manner, each time one light-transmissive member is laminated with the adhesive layer interposed therebetween, the adhesive layer is cured by irradiating with ultraviolet rays.
The laminated body shown in FIG. 18 is obtained. FIG. 19 shows how the laminate thus obtained is cut. The laminate is
In FIG. 18, it is placed on the cutting table 410 with the side face which is in contact with the vertical wall 404 facing down. Then, the cutting is performed along the parallel cutting lines 328a and 328b. After that, the cut surface is polished flat to obtain an element similar to that of the polarization beam splitter array of the first embodiment shown in FIG. However, the polarization beam splitter array produced in the second embodiment has dummy glass 32 at the end.
4 are provided.

In the second embodiment, the adhesive layer is cured by irradiating with ultraviolet rays every time one transparent member is laminated through the adhesive layer, so that the transparent member is cured. The positional relationship between them can be accurately determined.
Further, with the irradiation of ultraviolet rays, since only one adhesive layer needs to be cured, there is also an advantage that the curing can be reliably performed. The polarization beam splitter array of the first embodiment can be assembled by the assembling method of the second embodiment.

By the same process as in the second embodiment,
A plurality of laminates (referred to as “unit laminates”) obtained by pasting one first translucent member 321 and one second translucent member 322 together are prepared in advance. ,
You may make it laminate | stack these unit laminated bodies one by one.
That is, one unit laminated body may be laminated via the adhesive layer, air bubbles in the adhesive layer may be expelled, and then the adhesive layer may be cured by irradiating with ultraviolet rays. Even with such a process, almost the same effect as described above can be obtained.

In any of the first to third embodiments, the accuracy of the thickness of the translucent members 321 and 322 can be controlled when polishing the respective surfaces. Further, the thickness of the adhesive layer can be made uniform by making the amount of adhesive applied and the pressure during the bubble erasing step uniform over the surface of the member.

C. Configurations of Polarization Illumination Device and Image Display Device: FIG. 6 is a schematic configuration diagram of a main part of a polarization illumination device 1 having the polarization beam splitter array according to the above-described embodiment in plan view. The polarized illumination device 1 includes a light source unit 10
And a polarization generator 20. The light source unit 10 is
A light beam with a random polarization direction including the s-polarized component and the p-polarized component is emitted. The light flux emitted from the light source unit 10 is converted by the polarization generation device 20 into one type of linearly polarized light whose polarization directions are substantially aligned, and illuminates the illumination area 90.

The light source section 10 comprises a light source lamp 101 and a parabolic reflector 102. Light source lamp 10
The light emitted from No. 1 is reflected in one direction by the parabolic reflector 102, becomes a substantially parallel light beam, and enters the polarization generation device 20. The light source optical axis R of the light source unit 10 is in a state of being shifted parallel to the system optical axis L by a constant distance D in the X direction. Here, the system optical axis L is the optical axis of the polarization beam splitter array 320. The reason for shifting the light source optical axis R in this way will be described later.

The polarized light generating device 20 includes the first optical element 20.
0 and a second optical element 300. Figure 7
It is a perspective view showing the appearance of the first optical element 200. Figure 7
As shown in, the first optical element 200 has a configuration in which a plurality of minute light beam splitting lenses 201 each having a rectangular contour are arranged vertically and horizontally. The first optical element 200 is arranged so that the light source optical axis R (FIG. 6) coincides with the center of the first optical element 200. Set each beam splitting lens 201 to Z
The outer shape viewed from the direction is set to be similar to the shape of the illumination region 90. In the present embodiment, the laterally long illumination area 90 in the X direction is assumed, and therefore the outer shape of the light beam splitting lens 201 on the XY plane is also laterally long.

The second optical element 300 of FIG. 6 includes a condenser lens array 310 and a polarization beam splitter array 320.
, A selective retardation plate 380, and an exit lens 390. As described with reference to FIG. 5, in the selective retardation plate 380, the λ / 2 retardation plate 381 is formed only on the emission surface portion of the second translucent member 322, and the first translucent member 3 is formed.
The emitting surface portion of 21 is a colorless transparent plate-like body. In the polarization beam splitter array shown in FIG. 6, the protruding portions at both ends of the structure shown in FIG. 4 are cut into a substantially rectangular parallelepiped shape.

The condenser lens array 310 has substantially the same structure as the first optical element 200 shown in FIG. That is, the condenser lens array 310 includes the first optical element 2
00, a plurality of condensing lenses 311 of the same number as the light beam splitting lens 201 constituting 00 are arranged in a matrix.
The center of the condenser lens array 310 is also arranged so as to coincide with the light source optical axis R.

The light source section 10 emits a substantially parallel white light beam having a random polarization direction. The light flux emitted from the light source unit 10 and incident on the first optical element 200 is split into intermediate light fluxes 202 by the respective light flux splitting lenses 201. The intermediate light beam 202 is formed by the light beam splitting lens 201.
By the condensing action of the condensing lens 311, the light is converged within a plane perpendicular to the system optical axis L (XY plane in FIG. 1). At the position where the intermediate light beam 202 converges, the light beam splitting lens 20
The same number of light source images as the number of 1 are formed. The position where the light source image is formed is near the polarization separation film 331 in the polarization beam splitter array 320.

The light source optical axis R is deviated from the system optical axis L in order to form a light source image at the position of the polarization separation film 331. The shift amount D is set to 1/2 of the width Wp (FIG. 6) of the polarization separation film 331 in the X direction. As described above, the centers of the light source unit 10, the first optical element 200, and the condenser lens array 310 coincide with the light source optical axis R, and deviate from the system optical axis L by D = Wp / 2. There is. On the other hand, as can be understood from FIG.
The center of the polarization separation film 331 for separating the
Is deviated by Wp / 2. Therefore, the light source optical axis R is
By deviating from the system optical axis L by Wp / 2, the light source lamp 1 is provided substantially at the center of the polarization separation film 331.
The light source image of No. 01 can be formed.

The light beam incident on the polarization beam splitter array 320 is, as shown in FIG.
All are converted to s-polarized light. The light beam emitted from the polarization beam splitter array 320 illuminates the illumination area 90 by the emission side lens 390. Since the illumination area 90 is illuminated by the large number of luminous fluxes divided by the large number of luminous flux dividing lenses 201, the entire illumination area 90 can be uniformly illuminated.

When the parallelism of the light beam incident on the first optical element 200 is extremely good, the second optical element 30 is used.
It is also possible to omit the condenser lens array 310 from 0.

As described above, the polarized illumination device 1 shown in FIG.
Has a function as a polarization generation unit that converts a white light beam having a random polarization direction into a light beam having a specific polarization direction (s-polarized light or p-polarized light), and makes the illumination area 90 uniform with such a large number of polarized light beams. It has the function of illuminating. Since the polarized illumination device 1 uses the polarized beam splitter array 320 according to the embodiment, it has an advantage that the light utilization efficiency is higher than the conventional one.

FIG. 8 is a schematic configuration diagram showing a main part of a projection display device 800 equipped with the polarized illumination device 1 shown in FIG. This projection display device 800 includes a polarized illumination device 1,
Dichroic mirrors 801, 804 and reflection mirror 8
02,807,809 and relay lenses 806,80
8,810 and 3 liquid crystal panels (liquid crystal light valve)
803, 805, 811, a cross dichroic prism 813, and a projection lens 814.

The dichroic mirrors 801, 804 are
It has a function as a color light separation means for separating a white light flux into three color lights of red, blue and green. 3 liquid crystal panels 803
Reference numerals 805 and 811 each have a function as a light modulator that modulates the three color lights in accordance with the given image information (image signal) to form an image. The cross dichroic prism 813 has a function as a color light combining unit that combines color lights of three colors to form a color image. The projection lens 814 has a function as a projection optical system that projects light representing the combined color image on the screen 815.

Blue light / green light reflection dichroic mirror 801
Transmits the red light component of the white light flux emitted from the polarized lighting device 1 and reflects the blue light component and the green light component. The transmitted red light is reflected by the reflection mirror 802 and reaches the red light liquid crystal panel 803. On the other hand, the first
Of the blue light and the green light reflected by the dichroic mirror 801, the green light is reflected by the green light reflecting dichroic mirror 804 and reaches the green light liquid crystal panel 805. On the other hand, blue light is emitted from the second dichroic mirror 8
04 is also transparent.

In this embodiment, the optical path length of blue light is the longest of the three color lights. Therefore, for blue light, after the dichroic mirror 804, the incident lens 8
06, a relay lens 808, and a light guide unit 850 including a relay lens system including an emission lens 810 are provided. That is, the blue light is first transmitted through the green light reflecting dichroic mirror 804, and then first, the incident lens 8
06 and a reflection mirror 807, and then a relay lens 808.
Be led to. Further, the light is reflected by the reflection mirror 809 and guided to the emission lens 810, and the blue light liquid crystal panel 81.
Reach 1. The three liquid crystal panels 803, 805
811 corresponds to the illumination area 90 in FIG.

Three liquid crystal panels 803, 805, 811
Modulates each color light in accordance with an image signal (image information) provided from an external control circuit (not shown), and generates color light including image information of each color component. The three modulated color lights are cross dichroic prism 81.
It is incident on 3. On the cross dichroic prism 813, a dielectric multilayer film that reflects red light and a dielectric multilayer film that reflects blue light are formed in a cross shape. Three color lights are combined by these dielectric multilayer films to form light representing a color image. The combined light is projected on a screen 815 by a projection lens 814 which is a projection optical system, and an image is enlarged and displayed.

In this projection type display device 800, as the light modulating means, liquid crystal panels 803, 805, 8 of a type that modulate a light beam (s-polarized light or p-polarized light) in a specific polarization direction.
11 is used. In these liquid crystal panels, polarizing plates (not shown) are usually attached to the incident side and the emitting side, respectively. Therefore, when the liquid crystal panel is irradiated with a light beam having a random polarization direction, about half of the light beam is absorbed by the polarizing plate of the liquid crystal panel and converted into heat. As a result, the light utilization efficiency is low, and
There is a problem that the polarizing plate generates heat. However, in the projection display device 800 shown in FIG. 8, the polarized illumination device 1 generates the light flux in a specific polarization direction that passes through the liquid crystal panels 803, 805, 811. The problems of absorption and fever have been greatly improved. Further, since this projection display apparatus 800 uses the polarization beam splitter array 320 according to the embodiment, there is also an advantage that the light utilization efficiency of the projection display apparatus 800 as a whole is improved.

The polarization beam splitter array 320
The reflective film 332 of the liquid crystal panels 803, 805, 811
It is preferable to form the dielectric multilayer film having a property of selectively reflecting only a specific polarization component (for example, s-polarized light) to be modulated. By doing this, the liquid crystal panels 803, 8
The problems of light absorption and heat generation in 05 and 811 can be further improved. As a result, the light utilization efficiency of the projection display apparatus 80 as a whole can be further enhanced.

As described above, by using the polarization beam splitter array according to this embodiment, the light utilization efficiency in the projection type display device can be improved as compared with the conventional one. Therefore, the image projected on the screen 815 can be made brighter.

The present invention is not limited to the above examples and embodiments, but can be implemented in various modes without departing from the scope of the invention.
For example, the following modifications are possible.

(1) The polarization beam splitter array according to the present invention can be applied not only to the projection display device shown in FIG. 8 but also to various other devices. For example,
The polarization beam splitter array according to the present invention can be applied to a projection display device that projects a monochrome image instead of a color image. In this case, in the device of FIG.
Only one liquid crystal panel is required, and the color light separating means for separating the light flux into three colors and the color light combining means for combining the light fluxes of the three colors can be omitted.

(2) In the embodiment shown in FIG. 5, light shielding means may be provided to prevent light from entering through the incident surface of the second light transmissive member. FIG. 9A is shown in FIG.
It is explanatory drawing which shows the state which provided the light shielding plate 340 in front of the optical element of the Example shown in FIG. This light shield plate 34
At 0, a light blocking portion 341 that blocks light and a light transmitting portion 342 that transmits light are alternately formed. The light shielding plate 340 is formed on the surface of a transparent plate material such as plate glass,
It is created by forming a light reflection film or a light absorption film as the light shielding portion 341. The light blocking portion 341 shields the entrance surface 327 from light, so that the entrance surface 32 of the second light transmissive member 322 is blocked.
It is provided corresponding to 7.

FIG. 9B shows the optical path of the light incident on the incident surface 327 of the second light transmissive member 322 when the light shielding plate 340 is not provided. Incident surface 32
The light that has entered 7 is reflected by the reflection film 332a,
It is separated into s-polarized light and p-polarized light by the separation film 331 above it. The p-polarized light is converted into s-polarized light by the λ / 2 retardation plate 381. On the other hand, the s-polarized light is reflected by the upper reflecting film 332b and is emitted from the emission surface 326. As can be seen from FIG. 9B, the s-polarized component of the light incident from the incident surface 327 is
The first optical adhesive layer 325a is passed twice before reaching the upper reflection film 332b, and the next optical adhesive layer 325 is passed.
Pass b once. On the other hand, the p-polarized component has two optical adhesive layers 325 before reaching the λ / 2 retardation plate 381.
Pass a and 325b twice each. As described above, when the light shielding plate 340 is not provided, the light incident on the incident surface 327 of the second light transmissive member 322 passes through the optical adhesive layer 325 many times. Therefore, FIG.
By providing the light shielding plate 340 as in (A), such light can be shielded.

Instead of providing the light shielding plate 340 separately from the polarization beam splitter array 320, the light shielding portion 341 is formed on the entrance surface 327 of the second light transmissive member 322 with a reflection film made of aluminum or the like. You may do it.

[Brief description of drawings]

FIG. 1 is a diagram showing a schematic configuration of a polarization conversion element.

FIG. 2 is a process sectional view showing a main process for manufacturing a polarization beam splitter array that is an embodiment of the present invention.

FIG. 3 is a process sectional view showing a main process for manufacturing a polarization beam splitter array that is an embodiment of the present invention.

FIG. 4 is a polarization beam splitter array 32 according to an embodiment.
The perspective view which shows 0.

FIG. 5 is a cross-sectional plan view showing the polarization conversion elements of the example and the comparative example in comparison.

FIG. 6 is a schematic configuration diagram of a main part of a polarization illumination device having a polarization beam splitter array according to an embodiment when seen in a plan view.

7 is a perspective view showing the outer appearance of the first optical element 200. FIG.

FIG. 8 is a projection display device 800 including the polarized illumination device 1.
FIG. 3 is a schematic configuration diagram showing a main part of FIG.

FIG. 9 is an explanatory diagram showing a configuration of an optical element having a light shielding plate 340.

FIG. 10 is a polarization beam splitter array 320 according to an embodiment.
Sectional drawing which expands and shows in detail.

11 is a cross-sectional view showing a state where a condenser lens array 310 in which a plurality of small lenses (condenser lenses) 311 are arranged in a matrix is provided on the light incident surface side of a polarization beam splitter array 320. FIG.

FIG. 12 shows the pitch of the polarized light separating film 331,
Explanatory drawing which shows the case where it sets to the value different from the pitch of the lens optical axis 311c of 11.

FIG. 13 is a plan view showing a condenser lens array 310 ′ having plural kinds of small lenses of different sizes and its B-
B sectional drawing.

FIG. 14 is an explanatory diagram showing a method of manufacturing the polarization beam splitter array in the second embodiment.

FIG. 15 is an explanatory diagram showing a method of manufacturing the polarization beam splitter array in the second embodiment.

FIG. 16 is an explanatory diagram showing a method of manufacturing the polarization beam splitter array in the second embodiment.

FIG. 17 is an explanatory diagram showing a method of manufacturing the polarization beam splitter array in the second embodiment.

FIG. 18 is an explanatory view showing a method of manufacturing the polarization beam splitter array in the second embodiment.

FIG. 19 is an explanatory diagram showing a method of manufacturing the polarization beam splitter array in the second embodiment.

[Explanation of symbols]

1 ... Polarized illumination device 10 ... Light source section 20 ... Polarization generator 22 ... Polarizing beam splitter array 30 ... Polarizing beam splitter 32, 34, 42, 44 ... Right angle prism 36 ... Polarization separation film 40 ... Prism 46 ... Reflective film 80 ... Projection display device 90 ... Illumination area 101 ... Light source lamp 102 ... Parabolic reflector 200 ... First optical element 201 ... Beam splitting lens 202 ... Intermediate luminous flux 300 ... Second optical element 310 ... Condensing lens array 311 ... Condensing lens 320 ... Polarizing beam splitter array 321 ... First translucent member 322 ... Second translucent member 325 ... Optical adhesive layer 326 ... Emitting surface 327 ... Incident surface 331 ... Polarization separation film 332 ... Reflective film 340 ... Shading plate 341 ... Shading section 342 ... Translucent part 380 ... Selective retarder 381 ... λ / 2 retardation plate 390 ... Emitting lens 800 ... Projection display device 801 ... Blue light green light reflection dichroic mirror 802, 807, 809 ... Reflective mirror 803, 805, 811 ... Liquid crystal panel 804 ... Green light reflection dichroic mirror 806 ... Incident lens 807 ... Reflective mirror 808 ... Relay lens 809 ... Reflective mirror 810 ... Emitting lens 813 ... Cross dichroic prism 814 ... Projection lens 815 ... Screen 850 ... Light guide means

   ─────────────────────────────────────────────────── ─── Continued front page       (56) Reference JP-A-4-310903 (JP, A)                 JP-A-7-43508 (JP, A)                 JP-A-7-221930 (JP, A)                 JP-A-62-234106 (JP, A)                 US Patent 2748659 (US, A)

Claims (4)

(57) [Claims] 1. A light from a light source is split into a plurality of intermediate light fluxes, each of the plurality of intermediate light fluxes is separated into two types of polarized light by an optical element, and then the light is converted by a polarization conversion means.
A polarized illuminating device converted into polarized light of a kind, wherein the optical element has a light incident surface and a light emitting surface substantially parallel to the light incident surface, and the light incident surface and the light emitting surface. A substantially parallel first and second film forming surfaces formed so as to form a predetermined angle with a polarization separation film formed without an optical adhesive layer on the first film forming surface, A plurality of first translucent members each including a reflective film formed on the second film formation surface without an optical adhesive layer interposed therebetween, and a plurality of the first transmissive members using an optical adhesive. A plurality of first light-transmissive members that are alternately laminated and each have a light-incidence surface and a light-emission surface formed on the same plane as the light-incidence surface and the light-emission surface of the first light-transmissive members comprising a second light-transmitting member, a plurality of small lenses arranged found on the light incident side of the optical element
Is, the intervals between the plurality of the polarization separation film in the optical element
However, it is different from the pitch of the lens optical axes of the plurality of small lenses.
The value is set to
Set so that it corresponds approximately to the pitch of multiple light beams emitted
The polarized illumination device. 2. The light from the light source is divided into a plurality of intermediate light fluxes.
Each of the plurality of intermediate light fluxes by an optical element
After separating into two kinds of polarized light, the polarized light conversion means 1
A polarized illuminating device that is converted into polarized light of a type, wherein the optical element has a light incident surface and a light emitting surface substantially parallel to the light incident surface.
The light incident surface and the light emitting surface at a predetermined angle.
Almost parallel first and second film formation surfaces formed in the manner described above.
And without forming an optical adhesive layer on the first film forming surface.
The formed polarization separation film and the second film formation surface are optically contacted with each other.
And a reflective film formed without an adhesive layer, respectively.
A plurality of first light-transmissive members that alternate with the plurality of first light- transmissive members using an optical adhesive.
And the light of the plurality of first translucent members bonded to each other.
Formed on the same plane as the incident surface and the light exit surface
A plurality of second light emitting surfaces each having a light incident surface and a light emitting surface.
A translucent member, and a plurality of small lenses are provided on the light incident surface side of the optical element.
Is, the intervals between the plurality of the polarization separation film in the optical element
However, it is different from the pitch of the lens optical axes of the plurality of small lenses.
Is set to a value that is close to the system optical axis of the polarized illumination device.
The peak position of the light intensity distribution emitted from the
Of the light incident on the polarization separation film on the light incident surface of the child.
It is set so that it is almost coincident with the center of the effective incident area, which is the projection surface.
A polarized light illuminator. 3. The polarized illumination device according to claim 1 , further comprising an adhesive layer on a boundary surface between the first and second translucent members, wherein the plurality of polarized lights are provided. The thickness of the first and second translucent members and the thickness of the adhesive layer are set such that the mutual spacing of the separation films substantially corresponds to the pitch of the plurality of light beams emitted from the plurality of small lenses. At least some of them are set,
Polarized lighting device. 4. The polarized illumination device according to claim 1 , wherein at least one end of the optical element has a dummy region in which neither the polarization splitting surface nor the reflecting surface exists. A polarized light illumination device, which is formed of a translucent member.