The present invention relates to an optical system having a reflective imaging element which is capable of forming an image of an object in a space and a display panel.
In recent years, an optical system for forming an image of an object in a space by using a reflective imaging element has been proposed (for example, Patent Documents 1 to 6). The optical system includes a reflective imaging element and an object, and an image to be displayed in a space is an image of the object, which forms at a position of planar symmetry with respect to the reflective imaging element as a plane of symmetry.
The reflective imaging element disclosed in Patent Document 1 has a plurality of throughholes penetrating through a plate-like substrate along its thickness direction, such that an optical element composed of two orthogonally-disposed specular elements is formed on the inner walls of each hole (see FIG. 4 of Patent Document 1), or has a plurality of transparent chimneys protruding in the thickness direction of the substrate, such that an optical element composed of two orthogonally-disposed specular elements is formed on the inner wall surface of each chimney (see FIG. 7 of Patent Document 1).
In the reflective imaging elements disclosed in Patent Documents 1, 2, and 5, tens to hundreds of thousands of square holes, each of whose sides measures about 50 μm to 1000 μm, are formed in a substrate having a thickness of 50 μm to 1000 μm, the inner surface of each hole being mirror coated by electroforming technique, nanoprinting technique, or sputtering technique.
An optical system in which a reflective imaging element is used utilizes specular reflection of the reflective imaging element, and, according to its principles, the ratio in size between the image of the object and the image appearing in the space is 1:1.
For reference sake, the entire disclosure of Patent Documents 1 to 6 is incorporated herein by reference.
[Patent Document 1] Japanese Laid-Open Patent Publication No. 2008-158114
[Patent Document 2] Japanese Laid-Open Patent Publication No. 2009-75483
[Patent Document 3] Japanese Laid-Open Patent Publication No. 2009-42337
[Patent Document 4] Japanese Laid-Open Patent Publication No. 2009-25776
[Patent Document 5] International Publication No. 2007/116639
[Patent Document 6] Japanese Laid-Open Patent Publication No. 2009-276699
In the aforementioned optical system, when an object is placed with a tilt relative to the reflective imaging element, the image (hereinafter referred to as an “aerial image”) appearing in the air also becomes angled, thus producing an effect of an aerial image floating in the space (PCT/JP2010/068966). Moreover, as the tilting angle of the object relative to the reflective imaging element is increased, a more upright image is formed as an aerial image in the air, whereby an image with enhanced reality can be displayed.
When an image which is displayed on a display panel is used as the object, the image which is displayed on the display panel appears upright in the air. Therefore, even though the image displayed on the display panel is a two-dimensional image, an aerial image would appear floating in the space to the viewer, thus resulting in a perception as if a three-dimensional image were being displayed in the air. In the present specification, an image which is perceived by a viewer as if a three-dimensional image were floating in the air in this manner may be referred to as an “airy image”. For reference sake, the entire disclosure of PCT/JP2010/068966 is incorporated herein by reference.
In the above optical system, as the tilting angle of the object relative to the reflective imaging element is increased, a more upright image is formed as an aerial image in the air, thus producing greater airiness. However, studies of the inventors have found a problem in that, depending on the structure of the reflective imaging element, increasing the tilting angle of the object may lead to an increase in the intensity of reflected light not contributing to image formation, such reflected light occurring at interfaces between media with different refractive indices, etc., thus deteriorating the contrast ratio of the aerial image.
The present invention has been made in order to solve the above problem, and an objective thereof is to provide an optical system having a reflective imaging element in which reflected light not contributing to image formation is reduced and whose imaging efficiency is improved.
An optical system according to the present invention is an optical system comprising: a display panel; and a reflective imaging element having a first principal face on which light emitted from the display panel is incident, a second principal face parallel to the first principal face, and two mutually-orthogonal specular elements being perpendicular to the first principal face, the optical system causing an image displayed on a display surface of the display panel to form an image at a position of planar symmetry with respect to the reflective imaging element as a plane of symmetry, wherein, the optical system further comprises a transparent substrate which is disposed on at least either the first principal face side or the second principal face side of the reflective imaging element; first light incident on the transparent substrate is linearly polarized light; and, given a proportion Rp of p-polarized light and a proportion Rs of s-polarized light in the first light incident on the transparent substrate, the proportion Rp of p-polarized light satisfies Rp×rp(θ)<r0×(Rp+Rs)−Rs×rs(θ), where: r0 is a reflectance for light perpendicularly incident on the transparent substrate; and rp(θ) is a reflectance for p-polarized light, and rs(θ) is a reflectance for s-polarized light, of the first light when the first light is incident on the transparent substrate at an incident angle θ. Note that, in the range 0°<θ<90°, 0≦Rp, Rs≦1, Rp+Rs=1, 0<r0<1, 0≦rp(θ)<1, 0<rs(θ)<1 are satisfied.
In one embodiment, the reflective imaging element includes a plate-like substrate having a plurality of throughholes along a thickness direction, and a transparent member filling the plurality of holes, and includes a transparent substrate only on the first principal face side, or on both the first principal face side and the second principal face side.
In one embodiment, the first light incident on the transparent substrate is composed only of p-polarized light.
In one embodiment, given a reflectance r0p for p-polarized light when light which is perpendicular to the transparent substrate is incident on the transparent substrate, the incident angle θ is an incident angle θ1 such that a reflectance rp(θ) of the p-polarized light is equal to or less than r0p/2.
In one embodiment, the incident angle θ is Brewster's angle.
Another optical system according to the present invention is an optical system comprising: a display panel; and a reflective imaging element having a first principal face on which light emitted from the display panel is incident, a second principal face parallel to the first principal face, and two mutually-orthogonal specular elements being perpendicular to the first principal face, the optical system causing an image displayed on a display surface of the display panel to form an image at a position of planar symmetry with respect to the reflective imaging element as a plane of symmetry, wherein, the reflective imaging element includes a plate-like substrate having a plurality of throughholes along a thickness direction, and a transparent member filling the plurality of holes, first light incident on the transparent member is linearly polarized light; and, given a proportion Rp of p-polarized light and a proportion Rs of s-polarized light in the first light incident on the transparent member, the proportion Rp of p-polarized light satisfies Rp×rp(θ)<r0×(Rp+Rs)−Rs×rs(θ), where: r0 is a reflectance for light perpendicularly incident on the transparent member; and rp(θ) is a reflectance for p-polarized light, and rs(θ) is a reflectance for s-polarized light, of the first light when the first light is incident on the transparent member at an incident angle θ. Note that, in the range 0°<θ<90°, 0≦Rp, Rs≦1, Rp+Rs=1, 0<r0<1, 0≦rp(θ)<1, 0<rs(θ)<1 are satisfied.
In one embodiment, the optical system further comprises a transparent substrate disposed on the second principal face side of the reflective imaging element.
In one embodiment, the first light incident on the transparent member is composed only of p-polarized light.
In one embodiment, given a reflectance r0p for p-polarized light when light which is perpendicular to the transparent member is incident on the transparent member, the incident angle θ is an incident angle θ1 such that a reflectance rp(θ) of the p-polarized light is equal to or less than r0p/2.
In one embodiment, the incident angle θ is Brewster's angle.
In any of the above embodiments according to the present invention, given a width a of one of the two specular elements of the optical system, a width b of the other specular element, and a height c of the two specular elements, and by defining an angle between a normal direction of the first principal face and an incident direction of second light incident on one of the specular elements an incident angle θ′, the incident angle θ′ is expressed by the following equation, when 0°<θ′<90°.
In one embodiment, defining an imaging efficiency of the optical system whose incident angle θ′ is expressed by the above equation to be 1, and defining an angle between a normal direction of the first principal face and an incident direction of second light incident on one of the specular elements as an incident angle θ′, the incident angle θ′ is an incident angle θ2 such that the imaging efficiency is equal to or greater than 0.5 but less than 1 when 0°<θ′<90°.
In one embodiment, the display panel is a liquid crystal display panel.
According to the present invention, an optical system having a reflective imaging element in which reflected light not contributing to image formation is reduced and whose imaging efficiency is improved is provided.
[
[
[
[
[
[
[
[
[
Hereinafter, embodiments of the present invention will be described with reference to drawings; however, the present invention is not limited to the illustrated embodiments.
With reference to
The optical system 100A, 100B shown in
With reference to
The optical element 10B shown in
a) and (b) are schematic perspective views of the unit imaging element 12A, 12B which is included in the respective reflective imaging element 11A, 11B, and are schematic diagrams showing a light path (arrows 60). As shown in
When light emitted from the display surface of the liquid crystal display panel 30 strikes the unit imaging element 12A, 12B, for example, as indicated by the arrows 60 in
Next, a method for suppressing reflected light not contributing to image formation will be described.
In the optical system 100A, 100B, a principal ray of first light (also referred to as incident light) which is emitted from the liquid crystal display panel 30 and strikes the first principal face of the optical element 10A, 10B is linearly polarized light. Defining the angle between the normal direction of the transparent substrate 21 (or the transparent resin 23B) and the direction of the first light striking the transparent substrate 21 (or the transparent resin 23B) as an incident angle, it is ensured that a proportion Rp of p-polarized light satisfies Rp×rp(θ)<r0×(Rp+Rs)−Rs×rs(θ) (hereinafter eq. (1)), where r0 is a reflectance for light perpendicular to the transparent substrate 21 (or the transparent resin 23B) when striking the transparent substrate 21 (or the transparent resin 23B), and, of the first light when striking the transparent substrate 21 (or the transparent resin 23B) at an incident angle θ, rp(θ) is a reflectance for p-polarized light (i.e., a light component which oscillates in parallel to the plane of incidence); Rp is a proportion of the p-polarized light; rs(θ) is a reflectance for s-polarized light of the first light; and Rs is a proportion of the s-polarized light. Note that, in the range 0°<θ<90°, 0≦Rp, Rs≦1, Rp+Rs=1, 0<r0<1, 0≦rp(θ)<1, 0<rs(θ)<1 are satisfied.
Since the principal ray of the incident light satisfies the aforementioned relationship, the proportion of the p-polarized light, which receives a small reflectance, becomes greater than the proportion of the s-polarized light, which receives a large reflectance. Therefore, reflected light can be suppressed at the plurality of interfaces between media of different refractive indices, so that the efficiency of light utility is enhanced and the stray light is suppressed, whereby the aerial image can have an improved visual recognition. It is more preferable if the principal ray of incident light is composed only of p-polarized light, because reflected light at the interface(s) will be further suppressed.
Next, the incident angle when light which is emitted from a display panel (e.g., the liquid crystal display panel 30) strikes the transparent substrate 21 or the transparent resin 23B which is included in the optical element 10A, 10B will be described.
a) is a graph showing a relationship between incident angles of light and reflectance at an interface between an acrylic substrate (refractive index: 1.49) and air. Note that this graph is obtained through a simulation. It can be seen that, with the incident angle of light on the acrylic substrate, s-polarized light (i.e., a light component which oscillates perpendicularly to the plane of incidence) and p-polarized light differ in reflectance.
a) is a partially-enlarged graph of the graph shown in
Next, imaging efficiency will be discussed. In the present specification, “imaging efficiency” is defined by eq. (2).
Imaging efficiency(%)=Ap×RA1×RA2×Rf2×100 (2)
Herein, Ap is an aperture ratio of throughholes at the first principal face side of the reflective imaging element 11A, 11B (or the proportion of the transparent resin 23B portion, which may hereinafter be referred to as the “throughhole aperture ratio”); RA1 is a proportion of the effective area at the first reflection; RA2 is a proportion of the effective area at the second reflection; and Rf is a specular reflectance of the specular element 14, 15. A proportion of a reflection effective area is obtained by dividing the geometric area of the reflection effective area by the geometric area of an area which is irradiated with incident light (proportion of reflection effective area=geometric area of reflection effective area/geometric area of area which is irradiated with incident light). As the imaging efficiency becomes closer to 100%, the light striking the reflective imaging element 11A, 11B is more efficiently utilized to form an image in the air.
a) and (b) are diagrams for specifically describing imaging efficiency. In these figures, it is assumed that the light incident on the reflective imaging element 11A, 11B first strikes the specular element 14, and reflected light thereof strikes the other specular element 15, and reflected light thereof contributes to image formation. It is assumed that the throughhole aperture ratio at the first principal face side (the light incident side) is 0.91, and that the specular reflectance is 1. Moreover, it is assumed that the light source provides collimated light with a uniform intensity distribution.
b) is a diagram for describing an optimum incident angle of light striking the first principal face of the reflective imaging element 11A, 11B. Assuming that, between the two specular elements 14 and 15 of the unit imaging element 12A, 12B, one specular element has a width a and the other specular element has a width b, and the two specular elements 14 and 15 have a height c, and defining the angle between the normal direction of the first principal face and the incident direction of second light striking one of the specular elements (14 or 15) as an incident angle θ′, an optimum incident angle θA which is in favor of imaging efficiency is expressed by eq. (3) below, when 0°<θ′<90°. Moreover, given an incident angle θ of the first light, an optimum viewing position would be at (90−θ) degrees above the second principal face of the optical element 10A, 10B (see
c) is a graph showing an imaging efficiency when collimated light strikes one specular element (14 or 15) of the reflective imaging element 11A, 11B at various incident angles. This graph is obtained through a simulation. In this case, the angle represented by eq. (3) above is an angle indicated as “θA” in the graph. As can be seen from
b) is a partially-enlarged graph of the graph shown in
a) is a schematic cross-sectional view showing an optical system 100C in which a light source (e.g., an organic EL panel) 31 other than a liquid crystal panel 30 is used as the light source, and is a schematic diagram showing a light path (arrows 61).
As shown in
In the case where a display panel which does not permit easy viewing angle control, e.g., an organic EL display or a plasma display, is used instead of a liquid crystal display panel 30, a display panel which is adapted to the desired viewing angle needs to be obtained by using a viewing angle controlling film (e.g., Light Control Film manufactured by Sumitomo 3M Limited). Furthermore, in the case where a projector or an LED display is used as the display panel, there is strong light directivity and a narrow viewing angle, so that a lens or the like for angling the rays (broadening the viewing angle) needs to be employed between the display panel and the optical element 10A, 10B.
Next, incident light characteristics for increasing the imaging efficiency will be discussed.
In the case where the aforementioned optical element 10A, 10B is used, the two following patterns of optical paths are possible.
Pattern 1: air layer/transparent substrate (e.g., an acrylic substrate)/air layer/reflection surface/air layer/reflection surface/air layer/transparent substrate (e.g., an acrylic substrate)/air layer
Pattern 2: air layer/transparent material (e.g., a transparent resin and acrylic substrate, or a transparent resin)/reflection surface/transparent material (e.g., a transparent resin)/reflection surface/transparent material (e.g., a transparent resin and acrylic substrate, or a transparent resin)/air layer
In each of these two patterns, there is more than one air layer/transparent substrate (or transparent material) interface of different refractive indices, and the reflection occurring at these interfaces lowers the efficiency of light utility (and also causes stray light). Therefore, it is important to suppress reflection at any interface between air layer/transparent substrate (or transparent material) of different refractive indices.
Therefore, in order to improve the efficiency of light utility, the inventors have dictated that the proportion of p-polarized light in the light being emitted from the display panel and incident on the first principal face of the optical element 10A, 10B satisfies the relationship of eq. (1), or that the incident light is composed only of p-polarized light.
From
In the two aforementioned optical path patterns, if the transparent substrate 21 (or the transparent resin 23B) all has the same refractive index, the image formation light intensity will be, respectively,
Pattern 1: image formation light intensity=incident light intensity×imaging efficiency×(metal reflectance)2×(1−interface reflectance)4
Pattern 2: image formation light intensity=incident light intensity×imaging efficiency×(metal reflectance)2×(1−interface reflectance)2.
Thus, zeroing the interface reflectance will be a factor for increasing the image formation light intensity.
a) is a schematic cross-sectional view for describing a path of light (arrows) when it strikes the transparent substrate 21, this light going out through the transparent substrate 21, and the outgoing light striking the reflective imaging element 11A (whose throughholes 22A are filled with air). Since the throughholes 22A in the reflective imaging element 11A are filled with air, the incident angle of light (θ1) and the outgoing angle (θ2) are equal (θ1=θ2). It is most preferable that the incident angle θ1 of the light striking the transparent substrate 21 is Brewster's angle θB. The incident angle θ2 of the light striking one specular element 14a (or 15a) which is included in the reflective imaging element 11A is most preferably the incident angle θA. Therefore, the structure of the reflective imaging element 11A (width a, width b, and height c of the unit imaging element 12A in
From manufacturing conveniences of the reflective imaging element 11A and the refractive index constraints on the transparent substrate 21 and the like, the incident angle θ1 on the transparent substrate 21 (or the transparent resin 23B) may be the aforementioned incident angle θB (θB−bm≦θB′≦θB+bp). Moreover, the incident angle θ2 on the specular element 14a (or 15a) included in the reflective imaging element 11A may also be the aforementioned incident angle θA′(θA−θHWHMθA≦θA′≦θA+θHWHM). So, they may be of the relationship satisfying θ1=θ2=θB′=θA′; the structure of the unit imaging element 12A is to be accordingly determined.
b) is a schematic cross-sectional view for describing a path of light (arrows) when it strikes the transparent resin 23B (or transparent liquid or solid) included in the reflective imaging element 11B. The transparent resin 23B (or transparent liquid or solid) has a refractive index n. In this case, the optimum incident angle θ1′ of the light striking the transparent resin 23B is Brewster's angle θB=tan−1(n). The optimum incident angle θ2′ of light striking one specular element 14b (or 15b) included in the reflective imaging element 11B is the incident angle θA. The incident angle θ2′ and the incident angle θ1′ are of the relationship expressed by eq. (5) below. Since θ2′=θA, θ1′=θB, the relationship of eq. (6) below is satisfied. Therefore, the refractive index of the transparent resin 23B (or transparent liquid or solid) and the unit imaging element 12B (width a, width b, height c of the unit imaging element 12B in
However, from manufacturing conveniences of the reflective imaging element 11B and refractive index constraints and the like, a relationship of eq. (7) below may be exploited, based on θ2′=θA′, θ1′=θB′.
c) is a schematic cross-sectional view showing a path of light (arrows) when it strikes the transparent substrate 21 and strikes the transparent resin 23B (or transparent liquid or solid) included in the reflective imaging element 11B. It is assumed that the transparent substrate 21 has a refractive index n and that the transparent resin 23B (or transparent liquid or solid) has a refractive index n′. In this case, preferably, the optimum incident angle θ1″ of the light striking the transparent substrate 21 is Brewster's angle θB=tan−1(n), and the optimum incident angle θ2″ of light striking one specular element 14b (or 15b) included in the reflective imaging element 11B is the incident angle θA. The incident angle θ2″ and the incident angle θ1″ have the relationship of eq. (8) below. Since θ2″=θA, θ1″=θB, the relationship of eq. (9) below is satisfied. Therefore, the refractive indices of the transparent substrate 21 and the transparent resin 23B (or transparent liquid or solid) and the unit imaging element 12B (width a, width b, height c of the unit imaging element 12B in
However, from manufacturing conveniences of the reflective imaging element 11B and refractive index constraints and the like, a relationship of eq. (10) below may be exploited, based on θ2″=θA′, θ1″=θB′.
As described above, in accordance with the optical system 100A, 100B of embodiments of the present invention, there is obtained an optical system having a reflective imaging element in which reflected light not contributing to image formation is suppressed and whose imaging efficiency is improved.
The optical systems of the aforementioned embodiments include a liquid crystal display panel emitting linearly polarized light as the display panel. However, without being limited thereto, a liquid crystal display panel emitting circularly polarized light or elliptically polarized light, or a display panel emitting unpolarized light can also be used in an optical system according to an embodiment of the present invention. In the case where any such display panel is used, a polarizer or the like may be provided between the surface of the display panel and a transparent substrate or transparent member for effecting conversion into linearly polarized light.
Industrial Applicability
The present invention is broadly applicable to any optical system which has a reflective imaging element capable of forming an image of an object in a space and a display panel.
10A, 10B optical element
11A, 11B reflective imaging element
12A, 12B unit imaging element
14, 14a, 14b, 15, 15a, 15b specular element
21, 21a, 21b transparent substrate
22A throughhole
23B transparent resin
30 liquid crystal display panel
40 position of image formation
100A, 100B, 100C optical system
Number | Date | Country | Kind |
---|---|---|---|
2010-104394 | Apr 2010 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/JP2011/060152 | 4/26/2011 | WO | 00 | 10/26/2012 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2011/136214 | 11/3/2011 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
7839574 | Okada et al. | Nov 2010 | B2 |
7965448 | Maekawa | Jun 2011 | B2 |
20010047846 | Currens et al. | Dec 2001 | A1 |
20090310231 | Maekawa | Dec 2009 | A1 |
20100214394 | Maekawa | Aug 2010 | A1 |
20100231860 | Maekawa | Sep 2010 | A1 |
20110235201 | Maekawa | Sep 2011 | A1 |
Number | Date | Country |
---|---|---|
06273608 | Sep 1994 | JP |
08169257 | Jul 1996 | JP |
2003517629 | May 2003 | JP |
2008-158114 | Jul 2008 | JP |
2009-025776 | Feb 2009 | JP |
2009-042337 | Feb 2009 | JP |
2009-075483 | Apr 2009 | JP |
2009-276699 | Nov 2009 | JP |
WO-2007116639 | Oct 2007 | WO |
WO-2011052588 | May 2011 | WO |
Entry |
---|
International Preliminary Report on Patentability dated Dec. 20, 2012. |
Javidi, B. et al. “Three-Dimensional TV, Video, and Display V,” Proceedings of SPIE, Oct. 3-4, 2006, vol. 6392, p. 1-8. Boston, MA. |
International Search Report PCT/ISA/210 for International Application No. PCT/JP2011/060152 dated May 23, 2011. |
Number | Date | Country | |
---|---|---|---|
20130038826 A1 | Feb 2013 | US |