JP4589691B2 - Stereoscopic optical image display window device - Google Patents

Description

The present invention relates to sterically color display to steric optical image display window device is Ru can recognize the object of interest by multiplying the brightness even a low light environment such as at night.

  In general, as one of the three-dimensional television systems capable of freely viewing a three-dimensional optical image from an arbitrary viewpoint, a three-dimensional IP (integral photography) three-dimensional system using convex lens groups or pinhole groups arranged on a plane. There are imaging devices and stereoscopic display devices. As an example of applying this IP three-dimensional system, a radial type gradient index lens having a specific length is known (for example, see Patent Document 1). The stereoscopic imaging device and the stereoscopic display device use an optical fiber lens as a radial type refractive index distribution lens, set the length to 3/4 period or 1/4 period of the meandering optical path, and the optical fiber lens It is configured to have a nonuniform bending distribution such as a square characteristic from the peripheral part toward the central part (GRIN lens).

  On the other hand, a photoelectric conversion tube (image intensifier) is known as an optical amplifying device capable of recognizing an image by multiplying the light even with a small amount of light (see, for example, Patent Document 2). This photoelectric conversion tube has a photocathode that makes light incident and converts it into electrons, a vacuum space that accelerates and sends electrons converted by this photocathode, and receives and multiplies electrons that are accelerated by this vacuum space and outputs them. A microchannel plate (MCP) that collides with electrons multiplied by the MCP, and emits electrons from each channel of the MCP as light of a specific wavelength, and is emitted from the phosphor screen It has a glass surface or a fiber optic plate that forms an image by making light incident and output.

  The photoelectric conversion tube having the above-described configuration has a configuration in which a bias voltage can be applied between the photocathode and the MCP, and a strip current flows by applying a voltage between the IN and OUT of the MCP. In addition, a voltage is applied between the MCP and the phosphor screen. Therefore, this photoelectric conversion tube can capture a clear image even in a low light environment when capturing an image of a subject, and can suppress the influence of the halo phenomenon.

In addition, a photographing camera that displays a photographed image using infrared rays without using a lighting device even at night, and a night vision camera that uses the above-described photoelectric conversion tube are generally known. Yes. The night vision camera includes: a photographing lens; a magnifying optical system that magnifies an optical image formed by the photographing lens; an image intensifier that enhances the optical image magnified by the magnifying optical system; A reduction optical system that reduces the optical image enhanced by the tensiifier; and an imaging unit that electronically picks up the optical image reduced by the reduction optical system. Therefore, according to this night vision camera, it is possible to photograph a subject even in an environment where there is little light (for example, see Patent Document 3).
JP-A-10-150675 (paragraph numbers 0025 to 0076, FIGS. 1 to 9) JP-A-6-295690 (paragraph numbers 0010 to 0013, FIG. 1) JP 2003-304435 A (paragraph numbers 0025 to 0073, FIGS. 1 to 3)

However, the following three-dimensional optical image display device using the IP three-dimensional system has the following problems.
That is, the conventional stereoscopic optical image display device using the GRIN lens needs to newly install a lighting device in a low light environment, and can display a subject clearly in an environment where the lighting device cannot be used. could not. Furthermore, the photographing unit and the display unit are separate, and cannot be operated as an integrated object.

An image intensifier that can display a subject image without using an illumination device even in a low light environment is a monochrome image and a two-dimensional planar image. It was.
And with a photographic camera using an image intensifier, the dichroic mirror can be used to shoot a subject image in color even in a low light environment. It has become a large and complex structure.

  In general, the window of a house or a window of a car is provided with a glass plate installed in a frame. At night, if a lighting device is not installed outside or outside the vehicle, Since the state outside the vehicle cannot be seen, a window that can be seen without a lighting device is desired.

The present invention has been made in view of the above problems, even with a small light environment, without using the illumination device, it can display a three-dimensional optical image in color with a simple structure, Ya buildings An object of the present invention is to provide a stereoscopic optical image display window device that can be installed on a window surface of a moving body such as a car.

In order to achieve the above-described object, a stereoscopic optical image display window device according to the present invention includes an incident-side element lens group in which incident-side element lenses are arranged in an array, and each incident side of the incident-side element lens group. An exit-side element lens group in which the exit-side element lenses are arranged in an array so that the optical axes of the element lenses coincide with each other, and an entrance-side RGB filter that is a red, green, and blue color filter provided in the incident-side element lens group And an output side RGB filter that is a red, green, and blue color filter provided in the exit side element lens group, and a photomultiplier that multiplies an optical image by the entrance side element lens group, as a stereoscopic optical image display device which is arranged between the element lens group and the exit-side element lens, provided in all or part of the window surface of a building or mobile, the incident-side RGB filter and the exit side RGB Filter is of the incident-side element lens and the exit-side element lens aligned provided so that the position of the red, green and blue on the optical axis coincides, two at predetermined intervals the window surface in a thickness direction It is configured to have a glass surface, and the exit side element lens group is installed on one side of the glass surface so as to be on the same plane, and the other side of the glass surface faces the entrance side element lens group, and An afocal lens group in which an afocal optical system that inverts the depth of an image is arranged in an array is arranged to be on the same plane , or the incident side element lens group is on the same plane on one of the glass surfaces. An afocal optical system that is arranged on the other side of the glass surface and that faces the exit-side element lens group and inverts the depth of the optical image in an array. It has a structure of arranging the lens group to have the same plane.

The stereoscopic optical image display window device configured in this way is installed in a window of a building or a window of a moving body such as a car, so that an element image incident from an incident side element image lens is photomultiplier. And is output as a stereoscopic optical image by the exit side element image lens. The output stereoscopic optical image is displayed in color by the incident side RGB filter and the emission side RGB filter. In addition, the stereoscopic optical image display window device can display a stereoscopic optical image having a correct depth in the same state as the subject by the afocal lens group.

In the stereoscopic optical image display window device, the photomultiplier includes an incident photocathode that generates photoelectrons, a microchannel plate that multiplies photoelectrons, and a light exit surface that has a phosphor screen that converts photoelectrons into an optical image. If, incident light conductive surface may be configured to include a voltage supply means for providing said microchannel plate and voltage on the phosphor screen.

The stereoscopic optical image display window device configured in this manner photoelectrically converts an optical image by an incident side element lens group by an incident photocathode to generate photoelectrons corresponding to the optical image, and the photoelectrons from the incident photocathode are microscopically converted. Multiplying by the channel plate, and photoelectrons from the microchannel plate can be converted into an optical image by the fluorescent screen and sent to the exit side element lens group as an element image group obtained by multiplying the light.

Furthermore, in the stereoscopic optical image display window device, one of the incident side element lens and the emission side element lens is a convex lens, or a GRIN lens that is a refractive index distribution lens having a refractive index different from the center toward the outer periphery, The GRIN lens is a 1/4 GRIN lens formed to have a length that is 1/4 of one period of the optical path meandering in the GRIN lens, and the other of the incident side element lens and the emission side element lens is A GRIN lens, which is a refractive index distribution lens having a refractive index that varies from the center toward the outer periphery, is used as a 3/4 GRIN lens formed to have a length that is 3/4 of one cycle of the optical path meandering through the GRIN lens. May be.

The stereoscopic optical image display window device configured in this way has either a convex lens or a 1/4 GRIN lens and a 3/4 GRIN lens so that the subject and the depth are in the same position from the incident side element lens group to the subject side. In addition, a color stereoscopic optical image is displayed.

In the stereoscopic optical image display window device, the incident-side element lens is a convex lens, or a GRIN lens that is a refractive index distribution lens having a different refractive index from the center toward the outer periphery, and the GRIN lens is placed in the GRIN lens. May be configured as a 1/4 GRIN lens formed to have a length that is 1/4 of one period of the meandering optical path, and the emission side element lens may be configured as a convex lens or a 1/4 GRIN lens .

In any case, the stereoscopic optical image display window device configured in this way displays a stereoscopic optical image from the exit-side element lens so that the distance between the subject and the incident-side element lens group is the same. The stereoscopic optical image at that time is displayed in color and the depth is reversed with respect to the subject.

Further, in the stereoscopic optical image display window device, the afocal lens group is a GRIN lens in which the afocal optical system is a refractive index distribution lens having a different refractive index from the center toward the outer periphery, and the GRIN lens is It may be formed to have a length that is a half cycle of the optical path meandering in the GRIN lens .

The stereoscopic optical image display window device configured in this manner outputs an optical image of a subject incident on the GRIN lens of the afocal lens group in a state where the depth is reversed. Display as an image.

And in the stereoscopic optical image display window device, the afocal lens group is formed by arranging the first lens element and the second lens element on the same optical axis as the afocal optical system, and focus and may be assumed to be a unit composite lens to match the front focal point of the second element of the first lens element.

The stereoscopic optical image display window device configured in this manner outputs the optical image of the subject incident on the unit compound lens of the afocal lens group in a state where the depth is inverted, so that the stereoscopic optical of the same depth as the subject is provided. Display as an image.

Then, in the three-dimensional optical image display window device, the incident-side element lens group and the exit-side element lens unit may be intended to comprise an optical shielding part for shielding light between adjacent said element lenses.
The stereoscopic optical image display window device configured as described above is in a state in which unnecessary light does not enter from the adjacent element lens.

The present invention has the following excellent effects.
The stereoscopic optical image display window device according to the present invention is provided on a part or all of a building window or a window of a car, a train, etc., so that an object outside or outside the vehicle can be stereoscopically optically installed without installing an illumination device. It can be observed in color as an image. Further, it is you to view at a predetermined position as a three-dimensional optical image of the subject and the depth and the same state by providing the afocal lens group.

Hereinafter, the best mode for carrying out the present invention will be described with reference to the drawings.
1A and 1B are schematic views schematically showing a cross-sectional state of the stereoscopic optical image display device, and FIG. 2 schematically shows a cross-sectional state of the stereoscopic optical image display device and positions of the subject and the stereoscopic optical image. FIG. 3 is a schematic diagram schematically showing the configuration of the GRIN lens of the stereoscopic optical image display device, and FIG. 4 is a positional relationship from the incident side RGB filter to the output side RGB filter of the stereoscopic optical image display device. It is a schematic diagram which shows.

  As shown in FIG. 1A, the stereoscopic optical image display apparatus A includes an incident side element lens group 1 installed on the subject side, an incident side RGB filter 2 provided in the incident side element lens group 1, and this An incident photocathode 3 to which the incident side element lens group 1 provided with the incident side RGB filter 2 is attached, a microchannel plate 4 for accelerating electrons sent from the incident photocathode 3, and a microchannel plate 4 An outgoing light surface 6 having a fluorescent screen 5 for converting electrons into an optical image, an outgoing side element lens group 8 attached to the outgoing light surface 6, and an outgoing side RGB filter 9 provided in the outgoing side element lens group 8. And a voltage supply means 7 for applying a voltage to the incident photocathode 3, the microchannel plate 4 and the phosphor screen 5. The light doubling device B is configured by including the incident photocathode 3, the microchannel plate 4, the outgoing light surface 6 provided with the fluorescent screen 5, and the voltage supply means 7.

  The incident side element lens group 1 is formed by arranging GRIN lenses as an incident side element lens in an array. As shown in FIG. 3, the GRIN lens used here is a 3/4 GRIN lens 1a having a length of 3/4 of one cycle of the optical path meandering in the GRIN lens. Then, by aligning the 3/4 GRIN lens 1a in an array, both end faces of the 3/4 GRIN lens 1a are aligned so as to be in the same plane, and are attached to the incident photocathode 3 as the incident side element lens group 1. .

In this case, the incident-side element lens group 1 has an aligned state in which the centers of the 3/4 GRIN lenses 1a coincide with each other and the centers of the 3/4 GRIN lenses 1a coincide with each other in the columns. It is arranged as a stacking state. Note that the alignment state of the 3/4 GRIN lenses 1a may be a state in which the centers of adjacent 3/4 GRIN lenses 1a are aligned vertically and horizontally. That is, as long as the optical axis of each element lens in the incident side element lens group 1 and the optical axis of the element lens in the emission side element lens group 8 coincide with each other, the arrangement of these element lenses is not limited to the stacked state.
The optical image of the subject incident on the incident side element lens group 1 is incident on each 3/4 GRIN lens as an element image and is output to the incident photocathode 3.

  As shown in FIG. 4, the incident-side RGB filter 2 is a color filter, and is formed as a set of three elements of three colors of R (red), G (green), and B (blue). The incident side RGB filter 2 is provided on the incident end face of the incident side element lens group 1. The incident-side RGB filter 2 may be provided on the exit end face of the incident-side element lens group 1. The incident-side RGB filter 2 is provided in the incident-side element lens group 1, so that an element image filtered by each color of R, G, and B is input as incident light to the incident photocathode 3 via the incident-side element lens group 1. It is made incident on.

  The incident photocathode 3 photoelectrically converts incident light filtered by the incident-side RGB filter 2 into a number of photoelectrons corresponding to its brightness. Incident light incident on the incident photocathode 3 is output to the microchannel plate 4 as photoelectrons.

The microchannel plate 4 is a collection of a great number of channels (about 10 μmφ each) for multiplying photoelectrons, and has a multiplication factor of about 10 ⁴ . In the microchannel plate 4, incident electrons collide with the channel wall and are emitted as secondary electrons, and the emitted secondary electrons are accelerated by the voltage applied by the voltage supply means 7 and collide with the channel wall again. This is repeated and emitted from the output side as a large number of electrons. The microchannel plate 4 has a resistance value of a predetermined strip resistance (a total resistance value from the incident surface to the output surface of the microchannel plate) with respect to a predetermined effective diameter, so that the light intensity of incident light is reduced. When it is small, the multiplication factor is almost constant, and when it is large, the multiplication factor is lowered to suppress an increase in electrons. The electrons output from the microchannel plate 4 enter the phosphor screen 5.

  The phosphor screen 5 generates fluorescence by the collision of electrons multiplied by the microchannel plate 4. For example, the phosphor screen 5 is formed by applying a phosphor and depositing an aluminum metal back. The fluorescent screen 5 is an optical image incident on the incident photocathode 3 (fluorescence generated in a state where an element image is reproduced) is output from the outgoing light plane 6. Incidentally, electrons from the incident photocathode 3 to the phosphor screen 5 are output. The space in which is moved is configured to be maintained in a vacuum state.

  The voltage supply means 7 applies a high voltage from the outside to the incident photocathode 3, the microchannel plate 4, and the phosphor screen 5. Here, the voltage supply means 7 applies electrons using necessary elements such as a pulse generator and a capacitor, thereby generating electrons by parallel electric fields between the incident photocathode 3, the microchannel plate 4, and the phosphor screen 5. Is prevented from spreading. Here, for example, a voltage of 200 V is applied between the incident photocathode 3 and the microchannel plate 4, a voltage of 500 to 900 V is applied to the microchannel plate 4, and a voltage of 6 kV is applied between the microchannel plate 4 and the phosphor screen 5. The voltage of the microchannel plate 4 is variable.

  The outgoing light surface 6 is formed by a borosilicate glass (translucent member) whose focal plane is aligned with the fluorescent screen 5 or a fiber optical plate 6A as shown in FIG. A lens group 8 is attached. The fiber optical plate 6A is formed, for example, by bundling hundreds to tens of millions of optical fibers having a diameter of 6 μm, and the image is not distorted from the incident end surface to the output end surface by “light transmission” of the optical fiber. Communicating. An image emitted from the outgoing light surface 6 is input to the outgoing side element lens group 8.

  The exit side element lens group 8 is formed by arranging GRIN lenses as an exit side element lens in an array. The GRIN lens used here is a ¼ GRIN lens 8a having a length that is ¼ (see FIG. 3) of one cycle of the optical path meandering in the GRIN lens. The exit side element lens group 8 aligns the 1/4 GRIN lenses 8a in an array so that both end faces of the 1/4 GRIN lenses 8a are aligned on the same plane. Is attached. The exit side element lens group 8 is arranged so that the optical axis of the 1/4 GRIN lens 8a corresponds to the optical axis of the 3/4 GRIN lens 1a of the entrance side element lens group 1 (see FIG. 4). The exit side element lens group 8 is provided with an exit side RGB filter 9 on the exit end face.

  The output-side RGB filter 9 is a color filter, similar to the incident-side RGB filter 2, and is formed as a set of three elements of three colors of R (red), G (green), and B (blue). The emission-side RGB filter 9 is provided on the emission end face of the emission-side element lens group 8 and is arranged so as to coincide with the red, green and blue of the incident-side RGB filter 2. The output-side RGB filter 9 may be provided on the incident end face of the output-side element lens group 8. The emission-side RGB filter 9 is provided in the emission-side element lens group 8 so as to emit an element image filtered by each color of R, G, and B through the emission-side element lens group 8 as emission light. .

  In the stereoscopic optical image display device A configured as described above, the stereoscopic optical image S of the subject P is displayed in color as follows. That is, as shown in FIG. 2, the stereoscopic optical image display device A uses the optical image of the subject P incident from the incident-side element lens group 1 via the incident-side RGB filter 2 as an element image, and is incident on the photomultiplier B. The number of photoelectrons according to the brightness of the optical image of the element image is taken into the photocathode 3 and output from the photocathode 3.

  In the stereoscopic optical image display device A, an electron image by photoelectrons from the incident photocathode 3 is closely converged by an electric field by a voltage applied by the voltage supply means 7 between the incident photocathode 3 and the microchannel plate 4. Then, an image is formed on the input surface of the microchannel plate 4. Further, in the microchannel plate 4, the electrons are multiplied by about several thousand times when passing through, and the electrons are brought close to each other and accelerated by the electric field between the microchannel plate 4 and the phosphor screen 5.

  Then, in the stereoscopic optical image display device A, the electrons output from the microchannel plate 4 collide with the phosphor screen 5 to form optical images again, here, each element image is obtained. As what is enhanced 10,000 times, it is emitted through the emission side element lens group 8 and the emission side RGB filter 9 and is displayed in color as a stereoscopic optical image S.

  Therefore, as shown in FIG. 2, the element image is output through the emission side element lens group 8 and the emission side RGB filter 9 and is displayed as a stereoscopic optical image S having the same color as the subject P. The stereoscopic optical image S with respect to the subject P is displayed at a predetermined distance from the incident side element lens group 1.

  The positional relationship between the stereoscopic optical image S and the subject P is such that the distance from the subject P to the main plane of the incident side element lens group 1 of the stereoscopic optical image display device A is Ls, and the incident side element of the stereoscopic optical image display device A is. When the distance Lt is from the main plane of the lens group 1 to the main plane of the exit side element lens group 8, the display position of the stereoscopic optical image S is from the main plane of the exit side element lens group 8 of the stereoscopic optical image display device A. It becomes the position of the distance Ls. Note that the stereoscopic optical image S displayed here is displayed as an optical image in which the depth state is the same as that of the subject P. For this reason, the stereoscopic optical image display device A displays the stereoscopic optical image S of the subject P in color in the space from the incident side element lens group 1 to the subject side even in a dim state where the illumination state is not complete. Will be able to. The main plane is a plane in which the positions of the main points of the lenses are arranged on the same plane.

Next, the stereoscopic optical image display device A1 will be described with reference to FIG. In addition, the same code | symbol is attached | subjected about the same structure as the structure already demonstrated in FIG. 1 thru | or FIG. 4, and description is abbreviate | omitted.
In the stereoscopic optical image display device A1, the incident side element lens group 11 and the emission side element lens group 18 are different from those described in FIG.

  As shown in FIG. 5, the incident side element lens group 11 is formed by arranging convex lenses 11a as an incident side element lens in an array. The incident-side element lens group 11 is provided with the incident-side RGB filter 2 on the incident end face, and RGB is distributed to each convex lens 11a.

  The exit side element lens group 18 is formed by arranging convex lenses 18a as exit side element lenses in an array. In the exit side element lens group 18, the convex lens 18 a is arranged so that the optical axis of each of the convex lenses 11 a of the entrance side element lens group 11 coincides. Further, the emission side element lens group 18 is provided with an emission side RGB filter 9 on its emission end face. The emission-side RGB filter 9 is arranged so that RGB is distributed to each convex lens 18 a and coincides with the RGB of the incident-side RGB filter 2.

  When the optical image of the subject P is incident as an element image via the incident-side RGB filter 2 and the incident-side element lens group 11, the stereoscopic optical image display device A 1 configured in this manner is photoelectrically operated by the photomultiplier B. After being converted and multiplied, it is output via the exit side element lens group 18 and the exit side RGB filter 9.

  Then, the stereoscopic optical image display device A1 displays the stereoscopic optical image S of the subject P in color with the depth reversed with respect to the subject P and in color. At this time, the positional relationship between the stereoscopic optical image S and the subject P is such that the distance Ls from the subject P to the principal plane of the incident side element lens of the stereoscopic optical image display device A1 is the emission end face of the stereoscopic optical image display device A1. The stereoscopic optical image S is displayed at the position of the distance Ls from the distance.

  Further, instead of the convex lenses 11a and 18a, as shown in FIG. 6, 1/4 GRIN lenses 21a and 28a may be used as the incident side and outgoing side element lenses. That is, as shown in FIG. 6, the incident-side element lens group 21 is configured by arranging 1/4 GRIN lenses 21a in an array. The incident side RGB filter 2 is provided so that RGB is arranged corresponding to each 1/4 GRIN lens 21a.

  The exit-side element lens group 28 is provided with 1/4 GRIN lenses 28a arranged in an array as the exit-side element lens so as to coincide with the optical axis of each 1/4 GRIN lens 21a of the entrance-side element lens group 21. Has been placed. Further, the output side RGB filter 9 is arranged so that RGB (red, green and blue) is arranged corresponding to each 1/4 GRIN lens 28a and coincides with RGB (red, green and blue) of the incident side RGB filter 2. .

  The stereoscopic optical image display device A2 configured in this way displays the stereoscopic optical image S of the subject P in color with the depth reversed, as in the stereoscopic optical image display device A1. At this time, the positional relationship between the stereoscopic optical image S and the subject P is such that the distance Ls from the subject P to the principal plane of the incident side element lens of the stereoscopic optical image display device A1 is the emission end face of the stereoscopic optical image display device A1. The stereoscopic optical image S is displayed at the position of the distance Ls from the distance.

  Although not shown, the incident side element lens and the emission side element lens are arranged as the convex lens 11a and the 1/4 GRIN lens 28a, and the incident side element lens and the emission side element lens are 1/4 GRIN lenses. The apparatus may be configured as 21a and a convex lens 21a.

  Next, the stereoscopic optical image display device A3 will be described with reference to FIG. In addition, the already demonstrated structure attaches | subjects the same code | symbol and abbreviate | omits description. The stereoscopic optical image display device A3 is configured by installing an afocal lens group C that is a reversal optical system facing the incident side in the configuration of the stereoscopic optical image display device A1 (A2) already described. This afocal lens group C uses a GRIN lens, and is formed in an array with a half-cycle GRIN lens 1c, which is a half-cycle of the optical path meandering through the GRIN lens, as an element lens.

The installation position of the afocal lens group C is arbitrary as long as the optical image can be transmitted. In other words, the subject P and the inverted optical image R have the inverted optical image R at a distance Lo from the exit end surface of the afocal lens group C when the distance Lo from the incident end surface of the afocal lens group C to the subject P is set. It is formed. When the distance Lr is a distance from the reverse optical image R to the main plane of the incident-side element lens group 1 of the stereoscopic optical image display device A1, the distance from the main plane of the emission-side element lens group 8 of the stereoscopic optical image display device A1. The stereoscopic optical image S is displayed in color at the position Lr. Further, when the distance between the afocal lens group C and the principal plane of the incident-side element lens group 1 of the stereoscopic optical image display device A1 (A2) is Lif, the afocal lens group C and the stereoscopic optical image display device A1 (A2) ) Is positioned between the principal planes of the incident side element lens group 1 (Lif> Lo), the final optical image is the front side of the incident side element lens group 1 (opposite to the subject). Can be generated as an aerial image.

Next, the stereoscopic optical image display device A4 will be described with reference to FIG. In addition, about the structure already demonstrated, the same code | symbol is attached | subjected and description is abbreviate | omitted.
As shown in FIG. 8, the stereoscopic optical image display device A4 has a stereoscopic optical image Sp that has the same depth as the subject P with respect to the stereoscopic optical image S with the inverted depth displayed by the stereoscopic optical image display device A1 (A2). Can be displayed. This stereoscopic optical image display device A4 has an afocal lens in which an afocal optical system 1d, which is an element lens, is aligned in an array at a position separated from the stereoscopic optical image S displayed by the stereoscopic optical image display device A1 by a distance Lf. Group D is formed.

Afocal optical system 1d of the afocal lens group D may be, for example, focal length the same or different convex lenses (the first and second lens elements) 1 da, the partition plate 1g an optical shielding 蔽 unit to the optical axis of 1db Are arranged so that the focal length of the convex lens 1da on the optical axis (rear focal point) and the focal length of the convex lens 1db (front focal point) coincide with each other. The configuration of the afocal optical system 1d is called a Kepler type. The stereoscopic optical image Sp formed by the afocal optical system lens group D is formed by condensing the light rays from each afocal optical system 1d. In addition, although the first element and the second element are described as having the same focal length, the two do not necessarily have to be equal.

  It is assumed that the distance from the main plane of the exit side element lens group 8 of the stereoscopic optical image display device A1 to the stereoscopic optical image S is a distance Ls, and the distance from the incident end surface of the afocal optical system lens group D to the stereoscopic optical image S is a distance Lf. (Distance Laf from the main plane of the exit side element lens group 8 of the stereoscopic optical image display device A1 to the incident end face of the afocal optical system lens group D), and at a distance Lf from the exit end face of the afocal optical system lens group D The stereoscopic optical image Sp is displayed. The stereoscopic optical image Sp displayed here is displayed in color in the same depth state as the subject P. In particular, if the positional relationship is Laf> Ls, a stereoscopic optical image Sp can be generated as an aerial image behind the afocal lens group D (opposite the subject).

Here, since the afocal optical system 1d is not affected by extraneous light that crosses over from the other adjacent afocal optical system 1d, the interference can be avoided. Although not shown, also in the incident-side element lens group 11 and the exit-side element lens group 1 8, provided adjacent the element lens (11a, 21a, 18a, 28a) optical shielding on 蔽 unit (not shown) configured It doesn't matter.
Also in the stereoscopic optical image display device A shown in FIG. 1, it may be provided an optical shielding 蔽 unit (not shown) similarly to the adjacent element lenses (1a, 8a).

Next, the case where the stereoscopic optical image display devices A and A3 are installed in the window frame of the building to form the stereoscopic optical image display window devices 10 and 10A will be described with reference to FIGS. In addition, the already demonstrated structure attaches | subjects the same code | symbol and abbreviate | omits description.
As shown in FIG. 9, the stereoscopic optical image display window device 10 has a configuration in which the stereoscopic optical image display device A is provided on a part of the window surface 35 of the building 30. In this stereoscopic optical image display window device 10, the stereoscopic optical image display device A is installed through a partition frame 38 at a predetermined position of the window glass 36 installed in the window frame 37. A voltage can be applied from an indoor outlet by an adapter 39 provided as a power supply means via a connection cord. Here, a sliding door type window is illustrated and described as an applied window, but a window of a single-opening type, a double-opening type, an inward-turning type, or a fitting-in type may be used.

  The adapter 39 may be provided with, for example, an unillustrated on / off switch, and the on / off switch may be used to control whether or not to supply voltage to the stereoscopic optical image display apparatus A. Further, when the thickness dimension of the stereoscopic optical image display device A is larger than the thickness of the window glass 36, the stereoscopic optical image display device A is arranged in a state of protruding to the side where it does not collide even if it intersects with the opposite window.

  For example, the stereoscopic optical image display window device 10 can be used for gardens that are not dimly observable by human eyes if there is a small amount of light leaking from other buildings, even if a lighting device such as a streetlight is not installed outside the room. Even in this case, in the range of the visual field of the stereoscopic optical image display device A, a subject can be displayed as a stereoscopic optical image by color display.

  As shown in FIG. 10, when the window glass 36 is doubled, the stereoscopic optical image display device A <b> 3 may be a stereoscopic optical image display window device 10 </ b> A installed through a partition frame 38. In this stereoscopic optical image display window device 10A, the stereoscopic optical image display device A1 (A2) is installed on one window glass 36, and the afocal lens group C (D) is installed on the other window glass 36. A stereoscopic optical image is displayed in color on the indoor side.

In addition, it does not matter as a structure which installs another above-mentioned stereoscopic optical image display apparatus in the stereoscopic optical image display window apparatus 10 and 10A shown in FIG. 9 and FIG. Further, the stereoscopic optical image display window devices 10 and 10A are configured to stop the supply of voltage by removing the adapter 39 from the outlet when the daytime light is strong.
Moreover, although not shown in figure, it is good also as a structure installed similarly to the building 30 in some windows (side windows etc.) of moving bodies, such as a motor vehicle and a train.
Also, stereo-optic image display device A, (A1, A2) is adjacent the element lenses (1a, 8a, 11a, 21a , 18a, 28a) provided with intervening optical shielding 蔽 portion (not shown) configured It doesn't matter.

  In the above description, a photoelectric conversion tube (image intensifier) is shown as an embodiment as an optical amplifying device that can recognize light by multiplying light. It is also possible to employ a configuration using a composite element in which a photocurrent multiplication element and an electroluminescence element (EL) for multiplying the light intensity are used (organic pigment / metal interface ultrafine structure is used as the multiplication current characteristic).

(A), (b) is a schematic diagram which shows typically the cross-sectional state of the stereo optical image display apparatus used for the stereo optical image display window apparatus which concerns on this invention. It is a schematic diagram which shows the positional relationship of a to-be-photographed object and a stereo optical image while showing typically the cross-sectional state of the stereo optical image display apparatus used for the stereo optical image display window apparatus concerning this invention. It is a schematic diagram which shows typically the structure of the GRIN lens of the stereo optical image display apparatus used for the stereo optical image display window apparatus which concerns on this invention. It is a schematic diagram which shows the positional relationship from the incident side RGB filter of the stereo optical image display apparatus used for the stereo optical image display window apparatus which concerns on this invention to the output side RGB filter. It is a schematic diagram which shows the state which uses the convex lens for the incident side element lens of the stereo optical image display apparatus used for the stereo optical image display window apparatus which concerns on this invention, and an output side element lens. It is a schematic diagram which shows the state which uses the 1/4 GRIN lens for the entrance side element lens of the stereo optical image display apparatus used for the stereo optical image display window apparatus which concerns on this invention, and an output side element lens. It is a schematic diagram which shows the stereo optical image display apparatus which has arrange | positioned the afocal lens group used for the stereo optical image display window apparatus which concerns on this invention in front of the input side element lens group. It is a schematic diagram which shows the stereo optical image display apparatus which has arrange | positioned the afocal lens group used for the stereo optical image display window apparatus which concerns on this invention behind the output side element lens group. It is a perspective view which shows the stereo optical image display window apparatus which concerns on this invention. It is sectional drawing which shows typically the other structure of the stereoscopic optical image display window apparatus which concerns on this invention.

Explanation of symbols

A Stereoscopic image display device B Photomultiplier C Afocal lens group D Afocal lens group P Subject S Stereoscopic image 1 Incident side element lens group 1a 3/4 GRIN lens (incident side element lens)
2 Incoming RGB filter 3 Incoming photocathode 4 Microchannel plate 5 Fluorescent screen 6 Emission light surface 7 Voltage supply means 8 Emission side element lens group 8a 1/4 GRIN lens (outgoing side element lens)
9 Output side RGB filter 10 Stereoscopic optical image display window device 30 Building 35 Window surface

Claims (1)

The incident-side element lens group in which the incident-side element lenses are arranged in an array and the output-side element lens are aligned in an array so that the optical axes of the incident-side element lenses in the incident-side element lens group coincide with each other. An exit-side element lens group, an incident-side RGB filter that is a red-green-blue color filter provided in the incident-side element lens group, and an exit-side that is a red-green-blue color filter provided in the exit-side element lens group A stereoscopic optical image display device comprising an RGB filter and a photomultiplier that multiplies an optical image by the incident-side element lens group, disposed between the incident-side element lens group and the emission-side element lens group As provided on all or part of the window of the building or moving body,
The incident-side RGB filter and the emission-side RGB filter are provided so that the positions of the red, green, and blue are aligned on the optical axes of the incident-side element lens and the emission-side element lens,
The window surface is configured to include two glass surfaces with a predetermined interval in the thickness direction, and the exit side element lens group is installed on one of the glass surfaces so as to be in the same plane ,
On the other side of the glass surface, an afocal lens group in which an afocal optical system that inverts the depth of an optical image is arranged in an array so as to face the incident-side element lens group is arranged in the same plane , Or
The incident-side element lens group is installed on one side of the glass surface so as to be in the same plane, and the other side of the glass surface is opposed to the emission-side element lens group to reverse the depth of the optical image. A three-dimensional optical image display window device, wherein afocal lens groups in which focal optical systems are arranged in an array are arranged on the same plane .

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