KR101419448B1 - Four beam splitting method and A stereoscopic projection using the same - Google Patents

Abstract

The present invention relates to a four-path light division method which is used to divide an incident image signal to move in four paths and condense the split light beams to implement enhanced brightness and a stereoscopic image device thereof. The present invention includes: a light division device which reflects and divides the incident light to at least two directions based on the polarization properties of the incident light and transmits the divided light in one direction; a reflection module which reflects the light beams reflected and divided by the light division device respectively and provides the reflected light beams in a direction toward a screen; and a transmitted light reflection module which divides the light transmitted from the light division device in at least two directions by reflecting the light.

Description

[0001] The present invention relates to a four-beam splitting method and a stereoscopic projection apparatus using the same,

The present invention relates to a quadruple light dividing method capable of dividing an incident image signal so as to move along four paths and condensing the divided lights on a screen to realize an improved brightness, and a stereoscopic image apparatus using the same.

FIG. 1 shows a structure of a conventional optical splitter.

Light having P- polarized light is transmitted through the optical splitter 1 (PBS (Polarizing Beam Splitter)) in which the polarization direction is, for example, a mixture of P- and S-polarized light, and light having S-polarized light is reflected.

The reflected and transmitted S- and P-polarized light proceed in the same direction by rhombic prisms 2,3.

For example, light having P-polarized light is converted into P-polarized light to S-polarized light by the half-wave plate (retarder) 4 after passing through the prism.

As a result, the light having the P- and S-polarized light mixed by the disclosed optical splitter becomes the same polarized light, for example, S-polarized light, and can have the same direction.

Conventionally, the principle of operation of the stereoscopic image apparatus using the optical divider is as follows. See U.S. Pat. No. 7,857,455.

As shown in Fig. 2, the light emitted from the image plane 5, which generates an image in the projector, is divided into two lights in the light splitter 7 via the projection lens 6.

That is, the light having the S-polarized light and the P-polarized light component is reflected or transmitted by the light splitter 7.

The light having the transmitted P-polarized light component passes through the half-wave retarder 8 and becomes S-polarized light so as to be incident on the reflecting members 9 and 10, the polarizer 11 and the modulator 12 And then focused on the projection screen.

The modulator 12 can change the polarization direction by, for example, an electrical signal.

On the other hand, when the S-polarized light reflected by the light splitter 7 reaches the projection screen after passing through the reflecting member 13, the polarized light maintains the same direction.

Therefore, the light in which the polarization directions emerging from the image plane 5 are mixed becomes one S-polarized light.

The conventional problems of the conventional optical splitter are as follows.

Generally, the vertical angle of projection of the projector is about 15 degrees. In FIG. 3, the case where the angle of incidence is 15 degrees is shown, and the polarizer and the modulator are omitted to simplify the explanation.

The distances from the reflective members 16 and 17 to the other reflective members 17 and 17 in the light beam splitter are denoted by h ₁ and h ₂ respectively and the distances from the reflective members 16 and 17 to the screen 18 are denoted by L ₁ and L ₂ .

In this case, the reflecting member 16 and reflective member 17, the angle of optical axis of light emitted from the light and the projector forming reflection are respectively θ at ^{_{1 = TAN - 1 (h 1}} / L 1) and θ ₂ = TAN ^{- 1} (h ₂ / L ₂ ).

The phase distortion on the screen 18 by? ₁ and? ₂ is as follows. A portion of Fig. 3 is enlarged and shown in Fig.

The height difference d ₁ and d ₂ of the image on the screen 18 and the image forming surface of the light reflected by the reflecting member 16 and the reflecting member 17 are set so that the height of the screen 18 is H , The approximation is expressed as follows.

d ₁ = H TAN (? ₁ ), d ₂ = H TAN (? ₂ )

Therefore, the light reflected by the reflecting member 16 and the reflecting member 17 is formed in such a way that the difference in distance from the image plane is Δ = (H / 2) {TAN (θ ₁ ) + TAN (θ ₂ )} .

In the case of h ₁ = h ₂ = 340 mm, L ₁ = L ₂ = 15000 mm H = 8500 mm,? ₁ =? ₂ = 1.3?

This means that the light reflected by the reflective member 16 and the reflective member 17 is deviated by a maximum of 193 mm from the image plane and that the spot size of the light is usually several millimeters, And there is a practical restriction in use.

The present invention provides a method of dividing light in order to overcome the problem that such a conventional method does not coincide with the fact that two images are not coincident on the screen and the image quality is degraded and a large screen can not be realized, A stereoscopic image apparatus and a quadrant light splitting method that can obtain a high-quality screen while realizing a large screen by matching light on a screen and minimizing light loss.

Further, it is an object of the present invention to provide a space-saving arrangement in a stereoscopic image apparatus in a more intensive manner, and to provide an economical characteristic in production of a product.

According to an aspect of the present invention, there is provided a polarization beam splitter comprising: a light splitter that reflects incident light in at least two directions according to a polarization component, divides the light and transmits the divided light in one direction; A reflective light reflection module for reflecting the divided light reflected by the light splitter and providing the reflected light in a screen direction; And a transmitted light reflection module that reflects the light transmitted through the light splitter and divides the light into at least two directions.

According to another aspect of the present invention, there is provided a method of manufacturing an optical element, comprising: dividing incident light into two directions by reflecting and transmitting the light to and from a light splitter in accordance with a polarization component; And a step of moving the reflected light and the reflected light after passing through the screen to form an image so as to overlap on the screen, wherein the reflected light is transmitted to the screen by the path of the divided light and the path of the divided light, Wherein the light propagation path of the quadrupole light is at least four.

According to the present invention, it is possible to overcome the problem that the two images on the screen do not coincide with each other in the above-described conventional invention, thereby deteriorating the image quality and imposing a large screen.

That is, the light path is divided into two reflected light paths and two reflected light paths after being transmitted, and these are combined and synthesized again on the screen, so that the height error of the image can be remarkably reduced and a large screen can be realized.

According to the present invention, a part of light incident by a light splitter having a different arrangement angle and arranged in a symmetrical state with respect to an optical axis is reflected in two directions by a light splitter, reflected by each reflection light reflection module, At the same time, the light transmitted through the light splitter is reflected by the transmitted light reflection module and then directed to the screen.

Since the lights directed to the screen along the four different optical paths overlap each other on the screen, it is possible to realize a stereoscopic image capable of realizing high image quality and minimizing optical loss.

In addition, it is possible to increase the angle of divergence of the light by providing a separate structure on the optical path reflected after transmission, or by reducing the divergence angle of the reflected light by providing a separate structure on the reflected light path, The difference can be reduced, whereby the phase error can be remarkably reduced.

Further, there is an advantage that the optical splitter is composed of two optical transmitting members which are opposed to each other and a light splitting film interposed therebetween, whereby astigmatism of the light reflected and transmitted by the optical splitter can be eliminated.

On the other hand, since the distance between the light splitter and the reflective member becomes shorter than that of the conventional art, the size of the stereoscopic image apparatus is reduced, which contributes to the compactness of the product.

In addition, stereoscopic images can be easily realized even in a theater having a small projection ratio by using four different optical paths formed through light division, but the arrangement interval of components can be adjusted without increasing the size of the components inside the stereoscopic image apparatus , And economic efficiency related to the product cost can be achieved.

The effects obtained by the present invention are not limited to the above-mentioned effects, and other effects not mentioned can be clearly understood by those skilled in the art from the following description will be.

1 shows a light splitting method for implementing a single polarized light according to the prior art.
2 shows a structure of a conventional stereoscopic image apparatus.
FIGS. 3 and 4 are cross-sectional side views illustrating problems of the conventional stereoscopic image apparatus.
5 is a basic structure of a stereoscopic image apparatus according to the present invention.
6 is a view illustrating paths of light in a light splitter of a stereoscopic image apparatus according to the present invention.
FIG. 7 illustrates a light path in a state where a light refraction member is added to a stereoscopic image apparatus according to the present invention.
8 illustrates another embodiment of a light splitter in a stereoscopic image apparatus according to the present invention.
FIG. 9 shows a structure of a stereoscopic image apparatus according to the present invention in which a plurality of modulators are arranged.
FIG. 10 shows a structure in which a half-wave retarder is disposed in a stereoscopic image apparatus according to the present invention shown in FIG.
11 to 14 are side views of a structure for correcting the path of reflected light in the stereoscopic image apparatus according to the present invention.

Hereinafter, the present invention will be described with reference to the accompanying drawings.

5 shows a basic structure of a stereoscopic image apparatus according to the present invention.

Hereinafter, a video signal will be referred to as 'light' for the sake of convenience, and the word 'light' will be interpreted as meaning 'video signal'.

5, the light emitted from the image surface 19 and passing through the projection lens 20 is incident on the light splitter 20 in a state where the P-polarized light and the S- (PBS) 21 and 22, respectively.

For convenience, the optical splitter 21 is defined as a first optical splitter, and the optical splitter 22 is defined as a second optical splitter.

It is preferable that the optical splitters 21 and 22 are not implemented as one flat plate but have a bent section.

It is preferable that the centers of the optical splitters 21 and 22 are located on the optical axis of incident light and the first optical splitter 21 and the second optical splitter 22 are connected to each other, As shown in Fig.

That is, the first light splitter 21 and the second light splitter 22 are provided in a plate form, and are arranged in an inclined form in different directions.

The first light splitter 21 and the second light splitter 22 are arranged symmetrically with respect to the optical axis of the incident light.

Half of the light incident on the optical splitters 21 and 22 under this structure is incident on the first optical splitter 21 and the other half reaches the second optical splitter 22.

The light splitters 21 and 22 transmit a specific polarization component (P-polarization component), and the other polarization component (S-polarization component) is reflected in a direction different from the direction of the transmitted light, Role.

Therefore, the P-polarized light component of the light incident on the first optical splitter 21 is transmitted and travels in the screen direction.

On the other hand, the S-polarized light component of the light incident on the first light splitter 21 is reflected and travels in a first direction (upward direction in the figure).

Also, the P-polarized light component of the light incident on the second light splitter 22 is transmitted and travels in the screen direction.

On the other hand, the S-polarized light component of the light incident on the second light splitter 22 is reflected and travels in a second direction (downward direction in this figure).

That is, some of the incident light is reflected and the other is transmitted.

Reflected light reflection modules 23 and 24 such as mirrors are provided on the upper part of the first light splitter 21 and the lower part of the second light splitter 22,

The reflected light reflection modules 23 and 24 are representative of mirrors, but are not limited thereto, and all the components capable of realizing a light reflection function are possible.

Among the reflected light reflection modules 23 and 34, the one indicated by reference numeral 23 is defined as a first reflected light reflection member, and the one indicated by reference numeral 24 is defined as a second reflected light reflection member.

The light reflected from the first light splitter 21 and the first reflected light reflecting member 23 and the light reflected from the second light splitter 22 and the second reflected light reflecting member 24 are converted into S- And are directed to the screen and are merged on the screen.

It is preferable that the light reflected by the first and second light splitters 21 and 22 and directed in two directions is bisected by a cross section of incident light. The polarization components of the light reflected in the two directions are equal to each other.

On the other hand, the light transmitted through the first light splitter 21 and the second light splitter 22 has P-polarized light and is directed to the screen along the optical axis as it is.

Under such a structure, half of the light that has passed through the projection lens 20 reaches the first light splitter 21 before being reflected or transmitted, and the other half reaches the second light splitter 22, .

Therefore, when an image of the same size is projected on the screen, the distance between the light distributors 21 and 22 and the reflective members 23 and 24 can be remarkably reduced as compared with the prior art, This means that the device itself can be reduced in size.

If the distance between the light splitters 21 and 22 and the reflective members 23 and 24 is the same as that of the conventional art, the size of the image projected onto the screen can be remarkably larger than that of the conventional art.

On the other hand, the optical deflecting members 25 and 26 are provided in front of the optical splitters 21 and 22, respectively.

The function of the optical refraction members 25 and 26 is that light traveling along the optical axis of the light incident on the optical splitters 21 and 22 is extinguished by the optical splitters 21 and 22, And to prevent it.

The specific configuration and necessity of the optical refractive members 25 and 26 will be described later with reference to FIG. 6 and FIG.

The light transmitted through the light splitters 21 and 22 is divided in at least two directions by the first reflected light transmission module 31 disposed in the emission direction of the light splitters 21 and 22 and moved in the screen direction.

The transmitted light reflection module 30 is divided into a transmitted light first reflection module 31 and a transmitted light second reflection module 32.

The light transmitted through the light splitters 21 and 22 is reflected by the transmitted light first reflection module 31 and moves in different directions (upward and downward directions in the figure).

Whereby the transmitted light can be split in both directions.

The transmitted light first reflection module 31 is composed of a first transmission light reflection member 31a and a second transmission light reflection member 31b.

The first transmission light reflection member 31a and the second transmission light reflection member 31b are disposed to be inclined with respect to the optical axis of the light emitted from the projection lens 20 and are symmetrical with respect to the optical axis.

The first transmission light reflection member 31a and the second transmission light reflection member 31b may be connected to each other and may be formed in a bent shape.

That is, the reflection surface of the first transmission light reflection member 31a is tilted so as to be obliquely directed on the upper surface, and the reflection surface of the second transmission light reflection member 31b is tilted so that the lower surface thereof may be obliquely directed.

The transmitted-light second reflection module 32 reflects the light reflected by the transmitted-light first reflection module 31 and guides the reflected light to the screen.

The transmitted light second reflection module 32 includes a third transmitted light reflecting member 32a and a fourth transmitted light reflecting member 32b spaced apart from the third transmitted light reflecting member 32a.

It is preferable that the third transmission light reflection member 32a and the fourth transmission light reflection member 32b are arranged symmetrically with respect to an imaginary extension line of the optical axis of the light emitted from the projection lens 20. [

Therefore, the reflection surface of the third transmission light reflection member 32a is arranged so as to be able to obliquely face the lower surface, and the reflection surface of the fourth transmission light reflection member 32b is disposed so as to face the upper surface obliquely.

In this configuration, the light reflected and divided by the first transmitted-light reflecting member 31a is directed to the third transmitted-light reflecting member 32a and is reflected by the third transmitted-light reflecting member 31a before being directed to the screen.

Correspondingly, the light reflected and divided by the second transmitted-light reflecting member 31b is directed to the fourth transmitted-light reflecting member 32b, reflected therefrom, and then directed to the screen.

Therefore, the light reflected by the first and second reflected light reflecting members 23 and 24 and directed to the screen and the light reflected by the third and fourth transmitted light reflecting members 32a and 32b and directed to the screen can be superimposed on the screen have.

6, a substantial path of light passing through the first light splitter 21 and the second light splitter 22 in the absence of the optical refractive members 25 and 26 is shown.

As shown in FIG. 6, light incident on the first and second light splitters 21 and 22 with a diameter D is incident on the inclined first and second light splitters 21 and 22 Refract when transmitting.

In this case, most of the transmitted light passes through the first polarization splitter 21 and the second polarization splitter 22 and moves backward.

However, the light (expressed by the diameter d) in the central portion enters the first polarization splitter 21 and the second polarization splitter 22 and converges to one point.

Therefore, the light corresponding to the diameter d is lost without being directed to the screen.

That is, the light is incident on the bent portion between the first light splitter 21 and the second light splitter 22, and then converged to one point to form a dimming area (DA).

Part of the light passing through the light splitters 21 and 22 passes through the light extinction region DA and its energy is reduced, which results in lowering the luminous intensity on the screen, and is relatively dark in the entire screen area As a result.

Therefore, a correction method therefor is necessary, and FIG. 7 shows a structure in which the optical refractive members 25 and 26 are arranged as a part of the correction method.

As shown in FIGS. 5 and 7, optical refractive members 25 and 26 having refractive indexes and thicknesses similar to those of the first optical splitter 21 and the second optical splitter 22 are provided.

Each of the light refraction members 25 and 26 may be in the form of a plate, but is not limited thereto.

A portion of the optical refractive sheets 25 and 26 corresponding to the first optical splitter 21 is referred to as a first optical refractive sheet 25 and a portion corresponding to the second optical splitter 22 is referred to as a second optical refractor 25. [ Is defined as member (26).

The shapes of the first light refraction member 25 and the second light refraction member 26 are similar to those of the light splitters 21 and 22.

That is, the first light refraction member 25 is located at the center of the optical axis, and the second light refraction member 26 is located at the bottom of the first light refraction member 25, which are connected to each other.

And the arrangement thereof is preferably realized in a state (symmetrical state) facing the optical splitters 21 and 22.

The first and second light beam deflecting members 25 and 26 form a symmetrical state with respect to the optical axis of light emitted from the projection lens 20.

The first and second photoconfiguring members 25 and 26 are connected to each other and are inclined in different directions.

The path of light under this arrangement is as follows.

The light incident on the optical refractive members (25, 26) is refracted to change its path and move to the optical splitters (21, 22).

At this time, since the central portion of the light refraction members 25 and 26 is bent, a space region where light does not pass is formed between the central portion of the light refraction members 25 and 26 and the light splitters 21 and 22 EA: Empty Area) is formed.

The incidence path of the light incident on the light extinction area DA shown in FIG. 6 corresponds to the free area EA shown in FIG. 7. The light refraction member 25, 26 refracts the free area EA, The light is no longer incident on the light-extinguishing area DA, so that light loss due to light extinction can be prevented.

FIG. 8 shows a method for reducing astigmatism that may appear in a light splitter.

The components shown in FIG. 8 include a first light splitter 21, a first light refraction member 25, a first reflection member 23 and a description thereof with respect to the second light splitter 22, The member 26, and the second reflected light reflecting member 24, respectively.

When light that has passed through the first light beam deflecting member 25 reaches the first light splitter 21, the P-polarized light passes through the first light splitter 21 and the S-polarized light passes through the first light splitter 21) and is reflected by the first reflected light reflecting member (23).

At this time, the length of the path of the transmitted light is increased by the thickness T of the first light splitter 21 as compared with the path of the reflected light because the reflected light travels in the first optical splitter 21 The transmitted light passes through the first light splitter 21, whereas the light is not reflected but reflected from the surface.

In this case, astigmatism of light due to the path length difference between the reflected light and the transmitted light may occur.

It is necessary to correct the astigmatism so that the length of the path of the light reflected in the first light splitter 21 and the length of the path of the transmitted light.

Therefore, the first light splitter 21 is formed by joining two light transmitting members 211 and 212 having the same thickness, and a light splitting film 213 is formed therebetween.

Assuming that the thickness of the first light splitter 21 is T, the thickness of each of the light transmitting members 211 and 212 is t, and T = 2t (the thickness of the polarized light splitting film is ignored).

For convenience, let the thickness of the light transmitting member 211 located on the front side be t1 and the thickness of the light transmitting member 212 located on the rear side be t2.

Among the incident light, the P polarized light passes through the light transmitting member 211 on the front side, the light splitting member 213, and the light transmitting member 212 on the rear side.

At this time, the path length of the transmitted light in the first optical splitter 21 is t1 + t2.

On the other hand, among the incident light, the S polarized light passes through the light transmitting member 211 on the front side, reaches the light splitting film 213, is reflected, and passes again through the light transmitting member 211 on the front side.

At this time, the path length of the reflected light in the first optical splitter 21 is t1 + t1. Since t1 = t2, the path lengths of the reflected light and the transmitted light become equal to each other, thereby preventing the occurrence of astigmatism.

Although the incident angle, the transmission angle and the reflection angle of the reflected light and the transmitted light are not completely zero, the thickness of the first light splitter 21 and the light transmitting members 211 and 212 constituting the first light splitter 21 are very thin, The influence can be ignored.

The basic light dividing operation of the present invention will be described with reference to FIG.

The light emitted from the image plane 19 through the projection lens 20 passes through the light splitter 21 having a symmetrical structure through the light refraction members 25 and 26 in a state where P- and S- And 22, respectively.

The light refraction members 25 and 26 adjust the optical path so as to suppress loss at the center of the light which is refracted through the light.

The S-polarized light reflected by the optical splitters 21 and 22 is reflected again by the reflected light reflection modules 23 and 24 and travels to the screen. The S-polarized light reflected by the optical splitters 21 and 22, The light is reflected by the first transmitted light reflection module 31 (31a, 31b) and divided in both directions.

Light split in both directions reflected by the transmitted light first reflection module 31 (31a, 31b) is re-reflected by the transmitted light second reflection module 32 (32a, 32b) and is reflected in the same direction as the S- To the screen.

Thus, the path of the light reflected by the optical splitters 21 and 22 and the reflected light reflection modules 23 and 24 to reach the screen (for example, the path of light of the S-polarized component) (For example, a light path of a P-polarized component) that is reflected by the transmitted-light reflection module 30 and reaches the screen.

The effect of the polarization splitting method in the present invention is as follows.

The reflected S-polarized light is used, for example, in a half section, so that the distance between the optical axis of the projection lens 20 and other reflection modules is reduced to half compared with the conventional one, and substantially 75 mm or less is also possible.

This is lowered to 1/4 of 340 mm in the conventional method shown in FIG. 2, so that the angles? ₁ and? ₂ with the imaging plane on the screen 18 in FIG. 2 are about 1/4 of that in the conventional method The distance between the optical axis and the reflective members 16 and 17 is reduced to about 50 mm and the distance between the optical axis and the reflective members 16 and 17 is reduced to about 50 mm so that the deviation between transmission and reflected light is remarkably reduced.

Next, let us consider a case in which the present invention is applied to a stereoscopic image apparatus having enhanced brightness.

9, light (for example, S-polarized component light) emitted from the first reflecting light reflecting member 23 and the second reflecting reflecting member 24 is reflected by the first and second modulators 37a and 37c Lt; / RTI >

On the other hand, the light transmitted through the first light splitter 21 and the second light splitter 22 (for example, light of the P-polarized component) is modulated by the third modulator 37c.

The first modulator 37a and the second modulator 37b are provided to have the same phase delay function and the third modulator 37c is configured to generate a phase difference of a half wave with the first and second modulators 37a and 37c do.

The first and second modulators 37a and 37c modulate the states of light (e.g., S-polarized component light) emitted from the first and second reflected light reflecting members 23 and 24 by an electrical signal or the like And converts the linearly polarized light into the circularly polarized light state.

The first and second modulators 37a and 37b modulate the linearly polarized light into the circularly polarized light while maintaining the S-polarized state, thereby performing a 1/4 wavelength retardation function.

On the other hand, light (for example, P-polarized light) transmitted through the first light splitter 21 and the second light splitter 22 is modulated through the third modulator 37c (for example, S- Light) and is simultaneously modulated from the linear polarization state to the circular polarization state.

On the other hand, the third modulator 37c modulates the P-polarized state to the S-polarized state (performs a half-wave phase delay function), modulates the linearly polarized light to circularly polarized light And performs a 3/4 wavelength retardation function.

The light modulated by the third modulator 37c is incident on the transmitted light first reflection module 31 (31a, 31b), reflected, and divided so that the area thereof is divided into two portions so as to be divided in two directions.

The light split by the transmitted light first reflection module 31 (31a, 31b) is incident on the transmitted light second reflection module 32 (32a, 32b), thereby being transmitted in the screen direction.

The light modulated and reflected after the transmission is reflected and modulated (reflected by the light splitters 23 and 34) and then transmitted through the first reflection light reflection member 23 and the second reflection light reflection member 24 And modulated by the first and second modulators 37a and 37b) on the screen.

According to the present invention as described above, the number of paths of light projected and superposed on the screen is four.

For example, the path of the light reflected by the first light splitter 21, reflected by the first reflected light reflecting member 23, modulated by the first modulator 37a and directed to the screen becomes the first path.

The path of the light reflected by the second light splitter 22, reflected by the second reflecting mirror 24, modulated by the second modulator 37b, and directed to the screen is a second path.

On the other hand, the light is transmitted through the first light splitter 21, modulated by the third modulator 37c, reflected by the first transmitted-light reflecting member 31a and the third transmitted-light reflecting member 32a, The path of the light that is directed is the third path.

Finally, the light is transmitted through the second light splitter 22, modulated by the third modulator 37c, reflected by the second transmitted-light reflecting member 31b and the fourth transmitted-light reflecting member 32b, Is the fourth path.

In the embodiment shown in FIG. 9, it is preferable that the first to third modulators 37a to 37c are installed separately or separately from each other.

This is because the characteristics of the phase delay occurring in the first and second modulators 37a and 37b and the characteristics of the phase delay occurring in the third and fourth modulators 37c and 37b in the state where the first modulator 37a, the second modulator 37b, and the third modulator 37c are installed, ) Are different in the characteristics of the phase delay.

Also, instead of one third modulator 37c for modulating transmitted light, a modulator may be provided in front of the third transmission light reflection member 32a and before the fourth transmission light reflection member 32b, respectively.

That is, the light reflected from the third transmitted-light reflecting member 32a and the reflected light from the fourth transmitted-light reflecting member 32b are modulated by the respective modulators so that they can proceed to the screen.

Thus, by arranging the modulator in the vicinity of the exit region of the third transmitted-light reflecting member 32a and the fourth transmitted-light reflecting member 32b, higher-quality circularly polarized light can be incident on the screen.

FIG. 10 shows another embodiment in which an additional configuration is added to the embodiment shown in FIG.

FIG. 10 is a schematic diagram showing a configuration of the optical switch of FIG. 9, in which a half-wave retarder 38 is additionally used in the configuration of FIG. 9 to transmit the light transmitted through the first light splitter 21 and the second light splitter 22 (For example, light of a polarization component) into light having another polarization characteristic (for example, light of an S-polarization component).

The half-wave retarder 38 is disposed behind the optical splitters 21 and 22 and is disposed in front of the third modulator 37c.

That is, the half-wave retarder 38 is provided between the optical splitters 21 and 22 and the third modulator 37b.

Light having passed through the half-wave retarder 38 or light reflected by the first and second reflected light reflecting members 23 and 24 or light having the same polarization (for example, S-polarized light) characteristics .

In FIG. 10, the first modulator, the second modulator, and the third modulators 37a, 37b, and 37c all modulate linearly polarized light into circularly polarized light, thus performing a 1/4 wavelength retardation function.

In this configuration, after passing through the half-wave retarder 38, the light modulated by the third modulator 37c is incident on the transmitted-light first reflection module 31 (31a, 31b) So that the area of the optical path is divided in two directions so as to be directed in different directions.

Meanwhile, the light split by the transmitted light first reflection module 31 (31a, 31b) is incident on the transmitted light second reflection module 32 (32a, 32b), thereby being transmitted in the screen direction.

The transmitted light is reflected by the first and second reflected light reflecting members 23 and 24 and overlapped on the screen with the light modulated by the first and second modulators 37a and 37b.

According to the present invention as described above, similarly to the configuration of Fig. 9, there are four light paths projected on the screen and superimposed.

Since the specific light path is described in the description of FIG. 9, it is omitted.

In this case, a large one modulator may be used in place of the first, second and third modulators 37a, 37b and 37c, and all of them can be converted from linearly polarized light to circularly polarized light.

One such large modulator can convert incident light into quarter-wave phase retardation to linearly polarized light.

Although not shown in the drawing, the half-wave retarder 28 is disposed between the first reflective light reflection member 23 and the first modulator 37a, and the second reflective light reflection member 24 and the half- And the second modulator 37b.

(P-polarized light or S-polarized light) when both the light traveling along the reflection path and the light traveling along the reflection path after the transmission reach the screen.

Therefore, when the half-wave retarder 38 is disposed on the reflection path after the transmission, all the light reaching the screen can be brought into the S-polarization state to be imaged.

On the other hand, when the half-wave retarder 38 is disposed on the reflection path, all the light reaching the screen can be brought into the P-polarization state to be imaged.

Next, an image forming surface of the light reflected by the first light splitter 21 and the second light splitter 22 and an image of the reflected light transmitted through the first light splitter 21 and the second light splitter 22 A method of providing a screen of the same size on the screen will be explained by overcoming the difference between the screens when they can occur.

An image forming surface of the light primarily reflected by the first light splitter 21 and the second light splitter 22 and secondarily reflected by the reflected light reflecting modules 23 and 24, And a height difference between the image forming surfaces of the light transmitted through the first light splitter 21 and the second light splitter 22 and reflected by the first transmission light reflection module 31 and the second transmission light reflection module 32, May occur.

In this case, the image-forming surface of the light moving along the reflecting path is located in front of the image-forming surface of the light moving along the reflection path after the transmission, and a difference in height may occur due to such a difference in position.

A method of eliminating or minimizing the height difference can be achieved by adjusting the focal length. There are four methods as shown in Figs. 11 to 14.

In Figs. 11 to 14, the configurations of the modulator and the half-wave retarder are not shown, but it is natural that these components are substantially included.

First, as shown in FIG. 11, the first method is to increase the divergence angle of the transmitted light by using the lens 39 with respect to the light transmitted through the first light splitter 21 and the second light splitter 22 I will.

Here, since the lens 39 has to increase the divergence angle, it is desirable to have the characteristics of the concave lens.

According to this, the optical path corrected by the lens 39 by the optical path before correction by the lens 39 becomes more diverged, and the size of the image on the screen increases.

The size of the image formed on the screen by the light traveling along the reflection path after the transmission becomes equal to the size of the image formed on the screen by the light traveling along the reflection path, so that the height difference described above can be eliminated.

It should be noted that the lens 39 must be disposed between the two reflector rods so that light traveling along the reflector path is not interfered with the lens 39.

A second method for eliminating the height difference mentioned above is to provide lenses 40 and 41 for reducing the divergent angle of light on the reflecting mirror as shown in Fig.

Since the lenses 40 and 41 have to reduce the angle of divergence of light, it is necessary to provide some characteristics of the convex lens.

The lenses 40 and 41 are provided adjacent to the first reflection light reflecting member 23 and the first reflection light reflecting member 24 and the first reflection light reflection member 23 and the first reflection light reflection member 24 on the path of the reflected light.

According to this, the optical path corrected by the lenses 40 and 41 becomes less diverged by the optical path before correction by the lenses 40 and 41, and the size of the image on the screen is reduced.

The size of the image formed on the screen by the light traveling along the reflector path becomes equal to the size of the image formed on the screen by the light traveling along the reflection path after the transmission, so that the height difference described above can be eliminated.

It should be noted that the lenses 40 and 41 should be disposed outside the transmission path so that light traveling along the transmission path does not interfere with the lenses 40 and 41.

On the other hand, there is a method of correcting with the lenses 40 and 41 as shown in Fig. 12, but instead of the lenses 40 and 41, using a plate or prisms 42 and 43 for reducing the angle of divergence of light as shown in Fig. 13, May be corrected.

This is the third method of focal length adjustment to eliminate height differences.

Since the angle of divergence of light is required to be reduced in the plate or prism 42 or 43, it is necessary that the plate or prism 42 or 43 has some characteristics similar to those of a convex lens.

The plate or prism 42 or 43 is provided adjacent to the first reflection light reflection member 23 and the first reflection light reflection member 24 and is disposed adjacent to the first reflection light reflection member 23, It is preferable to be disposed on the traveling path of the light reflected by the member 24.

According to this, the optical path corrected by the plate or prisms 42, 43 is less diverged than the optical path before correction by the plate or prisms 42, 43, and the size of the image on the screen is reduced.

The size of the image formed on the screen by the light traveling along the reflector path becomes equal to the size of the image formed on the screen by the light traveling along the reflecting mirror after transmission, so that the height difference described above can be eliminated.

It should be noted that the plate or prism 42 or 43 must be disposed out of the transmission path so that light traveling along the transmission path does not interfere with the plate or prism 42 or 43.

The fourth method of focal length adjustment to eliminate height differences is to use reflective member-prism assemblies 44 and 45, as shown in Figure 14

The reflecting member-prism assemblies 44 and 45 are arranged such that the lenses 40 and 41 / plate or prisms 41 and 42 shown in Figs. 12 to 13 are spaced apart from the first and second reflecting light reflecting members 23 and 24 It is intended to make things easier.

The reflective member-prism assemblies 44 and 45 are characterized by reducing the angle of divergence of light.

The reflecting member-prism assemblies 44 and 45 are preferably disposed on the path of the light reflected by the first light splitter 21 and the second light splitter 22.

According to this, the optical path corrected by the reflecting member-prism assemblies 44 and 45 is less diverged than the optical path before being corrected by the reflecting member-prism assemblies 44 and 45, and the size of the image on the screen is reduced .

The size of the image formed on the screen by the light traveling along the reflector path becomes equal to the size of the image formed on the screen by the light traveling along the reflection path after the transmission, so that the height difference described above can be eliminated.

According to the present invention, the difference between the traveling path of the reflected light and the traveling path of the reflected light after the transmission can be reduced, so that a higher quality stereoscopic image can be obtained.

Furthermore, according to the present invention, it is possible to realize a stereoscopic image even in a theater having a low throw ratio.

The projection ratio is the ratio of the projection distance (the distance from the projection lens to the screen) divided by the width of the screen.

In a small theater with a small projection ratio, the projection distance is shorter than the screen width. In this case, the projector is placed in such a way that the light spreads to the wide angle. In this case, The internal optical elements can not but become large.

However, in the case of quadruple division of light as in the present invention, stereoscopic images can be realized even in a theater having a small projection ratio by arranging the intervals between the components densely without increasing the size of the optical elements therein.

Therefore, it is possible to realize the compactness of the equipment and the economical cost of the production.

It will be apparent to those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit of the invention. Accordingly, the above description should not be construed in a limiting sense in all respects and should be considered illustrative. The scope of the present invention should be determined by rational interpretation of the appended claims, and all changes within the scope of equivalents of the present invention are included in the scope of the present invention.

19: image plane 20: projection lens
21: first optical splitter 22: second optical splitter
23: first reflected light reflecting member 24: first reflected light reflecting member
25: first light refraction member 26: second light refraction member
30: transmitted light reflection module 31: transmitted light first reflection module
31a: first transmitted-light reflecting member 31b: second transmitted-light reflecting member
32: transmitted light second reflection module 32a: third transmitted light reflection member
32b: a fourth transmitted-light reflecting member
37a: first modulator 37b: second modulator
37c: third modulator 38: half-wave retarder
39, 40, 41: lens
42, 43: plate or prism
44, 45: Reflecting member - prism assembly

Claims (25)

A light splitter for reflecting the incident light in at least two directions according to a polarization component, dividing the light, and transmitting the divided light in one direction;
A reflective light reflection module for reflecting the divided light reflected by the light splitter and providing the reflected light in a screen direction;
And a transmitted light reflection module for reflecting the light transmitted through the light splitter and dividing the light into at least two directions. The method according to claim 1,
The polarization direction of the light reflected by the optical splitter becomes the same,
Wherein the light splitter comprises a first light splitter for reflecting a portion of the incident light in a first direction and a second light splitter for reflecting the incident light in a second direction,
Wherein the first light splitter and the second light splitter are disposed to be inclined toward different directions so as to be symmetrical with respect to an optical axis of the incident light. The method according to claim 1,
The reflective light reflection module
A first reflection light reflecting member for reflecting the light reflected by the light splitter and directed in a first direction toward the screen;
And a second reflection light reflecting member for reflecting the light reflected by the light splitter in a second direction toward the screen. The method according to claim 1,
A light splitter disposed in the traveling direction of light to be incident on the light splitter,
Further comprising a light refraction member for refracting the light to be incident on the optical splitters to prevent light from entering the optical extinction region formed in the optical splitter. The method according to claim 1,
The transmitted light reflection module
A first reflective module provided adjacent to the optical splitter and provided at a position where light transmitted through the optical splitter can be incident,
The transmitted light first reflection module includes:
A first transmission light reflection member that receives part of the transmitted light transmitted through the light splitter and is reflected in one direction, and a second transmission light reflection member that receives the remaining light transmitted through the light splitter and is reflected in the other direction . 6. The method of claim 5,
Wherein the first transmission light reflection member and the second transmission light reflection member are arranged to be inclined in a direction symmetrical with respect to an optical axis of the incident light. The method according to claim 1,
A half-wave retarder disposed between the optical splitter and the transmitted-light reflection module for delaying a half wavelength of the light transmitted through the optical splitter;
And a modulator disposed adjacent to the half-wave retarder. The method according to claim 1,
The transmitted light reflection module may include a first transmitted-light reflection module that reflects the transmitted light and divides it into two different directions;
And a transmitted light second reflection module for reflecting the light reflected by the first transmitted light reflection module and the divided light toward the screen direction,
And the transmitted light second reflection module includes a third and a third transmission light reflecting member for reflecting light in one direction and light in another direction, respectively, reflected from the transmitted light first reflection module. 9. The method of claim 8,
Wherein the third transmission light reflecting member and the fourth transmission light reflecting member are spaced apart from each other and are symmetrically provided with respect to an optical axis of transmitted light. The method according to claim 1,
A modulator for modulating the light reflected by the reflected light reflection module and directed to the screen,
And a modulator for modulating the light transmitted through the optical splitter. The method according to claim 1,
Further comprising a modulator for modulating the light reflected by the reflected light reflection module and directed to the screen and the light transmitted through the light splitter,
A reflector disposed between the optical splitter and the modulator or between the reflector and the modulator,
Further comprising a half-wave retarder for retarding the wavelength of the light transmitted through the optical splitter to the modulator by half a wavelength or for retarding the wavelength of light reflected by the reflected-light reflection module and directed to the modulator by half a wavelength. Imaging device. The method according to claim 1,
And a modulator for modulating the light reflected by the transmitted light reflection module and directed to the screen. The method according to claim 1,
A light source provided on a path of light transmitted through the light splitter
And a lens for adjusting a focal distance by increasing an angle of divergence of light transmitted through the optical splitter. The method according to claim 1,
And a light source provided in a path of light reflected by the reflected light reflection module,
And a lens for adjusting a focal distance by reducing an angle of divergence of light reflected by the reflected light reflection module. The method according to claim 1,
And a light source provided in a path of light reflected by the reflected light reflection module,
Further comprising a plate or prism for adjusting a focal distance by reducing an angle of divergence of light reflected by the reflected light reflection module. The method according to claim 1,
And a prism coupled with the reflective light reflection module,
Wherein the reflected light reflection module-prism assembly including the reflected light reflection module and the prism adjusts a focal distance by reducing an angle of divergence of light reflected by the reflected light reflection module. The method according to claim 1,
The optical splitter comprises:
A plurality of light transmitting members having the same thickness and arranged adjacent to each other;
And a light splitting film disposed between the light transmitting members and transmitting a part of the incident video signal and reflecting a part of the incident video signal in a plurality of directions. The method according to claim 1,
Wherein the light splitter includes two light splitting planes and a prism that corrects a path of light reflected from the light splitting plane and reduces a degree of divergence of reflected light. A part of the incident light is reflected and divided in at least two directions by a light splitter, and a part of the polarized light is transmitted through the light splitter;
Reflecting the polarized light component transmitted through the light splitter using a transmitted light reflection module and dividing the polarized light component into at least two directions;
A step of moving the light reflected by the light splitter and then reflected by the reflection light reflection module and the light reflected by the transmission light reflection module after passing through the light splitter to the screen so as to form an image on the screen Including,
And a transmission path of the light that is transmitted to the screen and overlapped by the path of the light reflected by the light splitter and divided by the light reflected by the transmitted light reflection module after passing through the optical splitter, is at least four How to quadruple. 20. The method of claim 19,
In the step of being reflected and split at least in two directions by the optical splitter,
Wherein the optical splitter divides the incident light so that an area of the incident light is bisected. 20. The method of claim 19,
Wherein the transmitted light reflection module divides the incident light so that the area of the incident light is bisected. 20. The method of claim 19,
Modulating the light reflected and moved by the light splitter;
Further comprising the step of modulating light traveling through the optical splitters. 20. The method of claim 19,
Modulating the light reflected and moved by the light splitter;
Modulating light traveling through the light splitter;
Further comprising the step of delaying the half-wavelength before modulating one of the reflected or transmitted light. 20. The method of claim 19,
Further comprising increasing an angle of divergence of light transmitted through the light splitter. 20. The method of claim 19,
Further comprising reducing an angle of divergence of light reflected and moved by the light splitter.

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