KR101960192B1 - Providing 3-dimensional image by using overlapped polarization - Google Patents

Abstract

A technique disclosed in the present specification, disclosed are a light splitter, which divides an incident light into a first polarized light and a second polarized light on the basis of a polarization direction and converts the second polarized light into the first polarized light, and a mirror for reflecting a superimposed first polarized light including the first polarized light and the converted first polarized light to a screen.

Description

PROVIDING 3-DIMENSIONAL IMAGE BY USING OVERLAPPED POLARIZATION [0002]

The present disclosure relates to providing stereoscopic images using superimposed polarized light.

Generally, incident light can be polarized through a stereoscopic imaging device. The polarized light produces images of alternating orthogonally polarized light on the screen.

Polarization selective glasses send images of one polarized light to the left eye and images of orthonormal polarized light to the right eye.

Thus, by providing different images to each eye of the user, a 3D image can be synthesized.

The technique disclosed in this specification provides a stereoscopic image device for improving the image quality and brightness of a stereoscopic image projected on a screen.

The stereoscopic image apparatus disclosed in this specification includes a light splitter that splits incident light into first polarized light and second polarized light based on a polarization direction, and converts the second polarized light into the first polarized light; And a mirror for reflecting the superimposed first polarized light including the first polarized light and the converted first polarized light to a screen.

Further, the light splitter may include a conversion module, and the conversion module may include a polarized light splitting part that reflects the first polarized light and passes the second polarized light.

The light splitter may include a phase shifter that phase-shifts the passed second polarized light by a quarter wavelength.

The optical splitter may include a beam splitter mirror that reflects the second polarized light phase-shifted by the 1/4 wavelength through the phase shifter to the mirror.

The phase shifter may further phase-shift the second polarized light shifted by the 1/4 wavelength reflected from the optical splitter mirror by a quarter wavelength, and further phase-shift the second polarized light by the quarter- May be the transformed first polarized light.

The optical system may further include a mirror prism disposed between the mirror and the light splitter and passing the superimposed first polarized light.

And a liquid layer that occupies a space corresponding to the optical path of the superimposed first polarized light between the mirror and the light splitter and passes the superimposed first polarized light.

Also, the transmittance of the liquid layer may be the same as the transmittance of the mirror prism.

Further, the liquid layer may be disposed between the mirror and the mirror prism, and the liquid layer may be in contact with the mirror and the mirror prism.

The liquid layer may be disposed between the mirror prism and the light splitter, and the liquid layer may be in contact with the mirror prism and the light splitter.

According to the technique disclosed in this specification, the image quality and the final brightness of the stereoscopic image projected on the screen are improved.

Further, according to the technique disclosed in this specification, the size of the stereoscopic image apparatus can be made compact.

In addition, according to the technique disclosed in this specification, it is possible to reduce the error in assembling the stereoscopic image apparatus, thereby improving the quality of the stereoscopic image projected on the screen.

1 is a diagram illustrating an exemplary stereoscopic imaging apparatus including one mirror.
2 is a diagram illustrating an exemplary stereoscopic imaging apparatus including two mirrors.
Figure 3 is a diagram showing an image on an exemplary cyclin.
4 is a diagram illustrating an exemplary stereoscopic imaging apparatus including one mirror.
5 is a diagram illustrating an exemplary stereoscopic imaging apparatus including two mirrors.
Figure 6 is a comparison of an air layer and a liquid layer.
7 is a diagram illustrating an exemplary mirror module.
8 is a view showing an example of using an exemplary stereoscopic image apparatus including one mirror.
9 is a view showing an example of using an exemplary stereoscopic image apparatus including two mirrors.
10 is a diagram illustrating an exemplary stereoscopic imaging apparatus including one mirror.
11 is a diagram illustrating an exemplary stereoscopic imaging apparatus including two mirrors.
12 is a diagram illustrating an exemplary stereoscopic imaging apparatus including one mirror.
13 is a diagram illustrating an exemplary stereoscopic imaging apparatus including two mirrors.

It is noted that the technical terms used herein are used only to describe specific embodiments and are not intended to limit the scope of the technology disclosed herein. Also, the technical terms used herein should be interpreted as being generally understood by those skilled in the art to which the presently disclosed subject matter belongs, unless the context clearly dictates otherwise in this specification, Should not be construed in a broader sense, or interpreted in an oversimplified sense. It is also to be understood that the technical terms used herein are erroneous technical terms that do not accurately represent the spirit of the technology disclosed herein, it is to be understood that the technical terms used herein may be understood by those of ordinary skill in the art to which this disclosure belongs And it should be understood. Also, the general terms used in the present specification should be interpreted in accordance with the predefined or prior context, and should not be construed as being excessively reduced in meaning.

As used herein, terms including ordinals, such as first, second, etc., may be used to describe various elements, but the elements should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the description of the technology, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, wherein like reference numerals denote like or similar elements, and redundant description thereof will be omitted.

Further, in the description of the technology disclosed in this specification, a detailed description of related arts will be omitted if it is determined that the gist of the technology disclosed in this specification may be obscured. It is to be noted that the attached drawings are only for the purpose of easily understanding the concept of the technology disclosed in the present specification, and should not be construed as limiting the spirit of the technology by the attached drawings.

1 is a diagram illustrating an exemplary stereoscopic imaging apparatus including one mirror.

Referring to FIG. 1A, the stereoscopic image apparatus may include at least one of a light splitter 110, a mirror 120, and / or a modulator 160.

The light splitter 110 can split the incident light (including the first polarized light and the second polarized light) into the first polarized light and the second polarized light based on the polarization direction, and convert the second polarized light into the first polarized light. The light splitter 110 can send the superimposed first polarized light to the mirror 120. [

The overlapped first polarized light may include a first polarized light and a converted first polarized light. The first polarized light may be S-polarized light and the second polarized light may be P-polarized. Further, the first polarized light may be P-polarized light and the second polarized light may be S-polarized light. The P-polarized light and the S-polarized light may be polarized light whose polarization directions are orthogonal to each other. Hereinafter, the first polarized light is S-polarized light, the second polarized light is P-polarized light, and the superimposed first polarized light is superimposed S-polarized light.

The light splitter 110 may include a conversion module.

The mirror 120 may reflect the superimposed first polarized light including the first polarized light and the converted first polarized light to the screen.

For example, the mirror 120 may be a mirror that totally reflects light. Further, the mirror 120 may be a glass and / or a reflective element that totally reflects light.

The mirror 120 can move. For example, the mirror 120 may be moved in the y-axis direction (the direction in which the superimposed S-polarized light reflected by the light splitter faces the mirror) or the x-axis direction (the direction in which the superimposed S- Can be moved.

In addition, the mirror 120 can rotate with respect to any axis (z axis) on the mirror 120.

The modulator 160 may selectively modulate the superimposed first polarized light into a first output polarized light that is synchronized with the image frame and corresponds to the left image frame or a second output polarized light that corresponds to the right image frame.

For example, the modulator 160 may change the polarization state of light by an electrical signal. The modulator 160 can modulate linearly polarized light into circularly polarized light.

Referring to Fig. 5 (b), a specific configuration of the conversion module is shown.

The light splitter 110 may include a conversion module. The conversion module may include at least one of a polarizing beam splitter 1171, a phase shifter 1173, and / or a beam splitter mirror 1175.

The polarized-light split section 1171 can reflect the first polarized light (S-polarized light) and pass the second polarized light (P-polarized light). The polarized light split section 1171 can reflect the first polarized light to the mirror 120 and pass the second polarized light to the phase shifting section 1173. [

For example, the first polarized light and / or the second polarized light may be linearly polarized light.

For example, the polarization split section 1171 may include a polarization beam splitter (PBS). In addition, the polarizing beam splitter 1171 may include a PBS coating.

The phase shifter 1173 can phase shift the incident light by a quarter wavelength.

For example, when the linearly polarized light is phase-shifted by 1/4 wavelength, it can be converted into circularly polarized light. Further, when the circularly polarized light is shifted by 1/4 wavelength, it can be converted into linearly polarized light.

Accordingly, when the incident light is linearly polarized light, the phase shifter 1173 can convert linearly polarized light into circularly polarized light. When the incident light is circularly polarized light, the phase shifter 1173 can convert circularly polarized light into linearly polarized light.

Further, when the first polarized light is phase-shifted twice (i.e., shifted by 1/2 wavelength) by 1/4 wavelength, the first polarized light can be converted into orthogonal second polarized light.

The phase shifter 1173 can phase-shift the second polarized light passed through the polarization splitters 1171 by a quarter wavelength. For example, the second polarized light (P-polarized light) is linearly polarized light, and the second polarized light 11731 shifted by 1/4 wavelength may be circularly polarized light.

The phase shifter 1173 can further phase-shift the second polarized light 11731 shifted by 1/4 wavelength reflected from the beam splitter mirror 1175 by a quarter wavelength.

For example, the second polarized light 11731 shifted by 1/4 wavelength is circularly polarized light, and the second polarized light 11737 phase-shifted by 1/4 wavelength may be linearly polarized light. In addition, the second polarized light 11737 phase-shifted by a quarter wavelength can be expressed by a first polarized light (S-polarized light) and / or a converted first polarized light (S-polarized light).

In this case, the polarization direction of the second polarized light 11737, the first polarized light (S-polarized light) and / or the converted first polarized light (S-polarized light) - polarized light).

For example, the phase shifter 1173 may include at least one of a quarter wavelength coating, and / or a quarter wavelength film.

The optical splitter mirror 1175 can reflect the second polarized light 11731 shifted by 1/4 wavelength through the phase shifter 1173 to the mirror 120.

The polarized-light split section 1171 reflects the first polarized light (S-polarized light) 11717 from the incident light. The beam splitter mirror 1175 reflects the second polarized light 11731 which is phase shifted by 1/4 wavelength. The second polarized light 11731 shifted by 1/4 wavelength is further phase shifted by a quarter wavelength by the phase shifter 1173 and converted into the converted first polarized light (S-polarized light 11737). The superimposed first polarized light may include a first polarized light (S-polarized light) 11717 and a converted first polarized light (S-polarized light) 11737. For convenience, the superimposed first polarized light can be expressed as being reflected by the mirror 120 by the light splitter 110.

For example, the beam splitter mirror 1175 may include at least one of a mirror, a total reflection glass, and / or a mirror-coated glass (BK-7).

The polarization splitters 1171, the phase shifters 1173, and / or the beam splitter mirrors 1175 may be sequentially arranged in a manner of being separated from each other, and may be sequentially arranged in a coupled manner.

The distance D between the first polarized light (S-polarized light) 11717 and the converted first polarized light (S-polarized light) 11737 due to the distance D between the polarized light separating portion 1171 and the light splitter mirror 1175 ) May occur.

However, it is also possible to coat all of the polarizing beam splitter 1171, the phase shifter 1173, and / or the beam splitter mirror 1175, or the distance D between the polarizing beam splitter 1171 and the beam splitter mirror 1175, The distance D can be minimized.

Thus, when the distance D is minimized, the first polarized light (S-polarized light) 11717 and the converted first polarized light (S-polarized light) 11737 can be superimposed substantially without error, It can be expressed by polarized light.

2 is a diagram illustrating an exemplary stereoscopic imaging apparatus including two mirrors.

A stereoscopic image apparatus may include at least one of a light splitter 110, a first mirror 120a, a second mirror 120b, and / or a modulator 160. [

The light splitter 110 can split the incident light (including the first polarized light and the second polarized light) into the first polarized light and the second polarized light based on the polarization direction, and convert the second polarized light into the first polarized light. The light splitter 110 can send the superimposed first polarized light to the mirror 120. [

The light splitter 110 may reflect some of the incident light to the first mirror 120a and reflect the remaining light to the second mirror 120b.

The light splitter 110 may include at least one of a first conversion module 117a and / or a second conversion module 117b.

For example, the first conversion module 117a can reflect half the first polarized light to the first mirror 120a with respect to the vertical direction cross section of the incident light. Also, the first conversion module 117a can convert half of the second polarized light into the first polarized light and transmit it to the first mirror 120a.

For example, the second conversion module 117b can reflect half of the first polarized light to the second mirror 120b with respect to the vertical direction cross section of the incident light. In addition, the second conversion module 117b can convert half of the second polarized light into the first polarized light and transmit it to the second mirror 120b.

The first mirror 120a receives the overlapped first polarized light (superimposed S-polarized light) corresponding to half of the light incident from the light splitter 110, and can reflect the superimposed first polarized light to the screen.

The second mirror 120b may receive the superimposed first polarized light (superimposed S-polarized light) corresponding to the other half of the light incident from the light splitter 110 and reflect the superimposed first polarized light to the screen.

For example, the superimposed first polarized light may include a first polarized light (S-polarized light) and / or a converted first polarized light (S-polarized light), and the first polarized light and / Lt; / RTI >

The modulator 160 may selectively modulate the superimposed first polarized light into a first output polarized light that is synchronized with the image frame and corresponds to the left image frame or a second output polarized light that corresponds to the right image frame.

For example, the modulator 160 may be integral or divided.

Referring to Fig. 5 (b), a specific configuration of the conversion module is shown.

The light splitter 110 may include at least one of a first conversion module 117a for processing a portion of the incident light and / or a second conversion module 117b for processing the remainder of the incident light.

The first conversion module 117a may include at least one of a first polarization split portion 1171a, a first phase shift portion 1173a, and / or a first optical splitter mirror 1175a.

The first polarized-light split section 1171a can reflect the first polarized light (S-polarized light) and allow the second polarized light (P-polarized light) to pass through a part of the incident light.

The first phase shifter 1173a can phase shift the incident light by a quarter wavelength. The first phase shifter 1173a can phase-shift the second polarized light passed through the first polarized-light splitter 1171a by a quarter wavelength.

In addition, the first phase shifter 1173a can further phase-shift the second polarized light 11731a shifted by 1/4 wavelength reflected from the first optical splitter mirror 1175a by a quarter wavelength.

The first beam splitter mirror 1175a can reflect the second polarized light 11731a shifted by 1/4 wavelength through the first phase shifter 1173a to the first mirror 120a.

The second conversion module 117b may include at least one of a second polarization split portion 1171b, a second phase shift portion 1173b, and / or a second optical splitter mirror 1175b.

The second polarized-light split section 1171b can reflect the first polarized light (S-polarized light) and allow the second polarized light (P-polarized light) to pass through the remainder of the incident light.

The second phase shifter 1173b can phase shift the incident light by a quarter wavelength. The second phase shifter 1173b can phase-shift the second polarized light passed through the second polarized-light splitter 1171b by a quarter wavelength.

The second phase shifter 1173b may further phase-shift the second polarized light 11731b shifted by 1/4 wavelength reflected from the second optical splitter mirror 1175b by a quarter wavelength.

The second beam splitter mirror 1175b can reflect the second polarized light 11731b shifted by a quarter wavelength to the second mirror 120b through the second phase shifter 1173b.

Between the first polarized light (S-polarized light) 11717a and the converted first polarized light (S-polarized light) 11737a due to the distance Da between the first polarized light split portion 1171a and the first optical splitter mirror 1175a An error of the first distance Da may occur.

The first polarized light (S-polarized light) 11717b and the converted first polarized light (S-polarized light 11737b) are reflected by the distance Db between the second polarized light split portion 1171b and the second optical splitter mirror 1175b. An error of the second distance Db may occur.

However, when the first distance Da and / or the second distance Db are minimized, the first polarized light (S-polarized light 11717a, 11717b) and the converted first polarized light (S-polarized light 11737a, 11737b) Can be substantially superimposed without error and can be represented by one superimposed first polarized light.

Figure 3 is a diagram showing an image on an exemplary cyclin.

Referring to Figure (a), an image according to the prior art is shown.

Keystoning is a phenomenon that occurs when the projector lens is not parallel to the screen surface, and a square or rectangular image is projected in a trapezoidal shape with the top side longer than the base side.

The light corresponding to the first polarized light and the light corresponding to the second polarized light proceed to the path through which the light corresponding to the first polarized light travels on the reflected path and the light corresponding to the second polarized light travels through, The length of the path is different. In this case, since there is a positional difference between the light corresponding to the first polarized light and the light corresponding to the second polarized light, and the path length is different, a keystone phenomenon occurs.

For example, a difference occurs between the image 191a by the first polarized light and the image 195a by the second polarized light on the screen. The image 191a by the first polarized light can be projected in a shape larger or more trapezoidal than the image 195a by the second polarized light.

Referring to Figure (b), there is shown an image according to the techniques disclosed herein.

The stereoscopic image device sends the superimposed first polarized light to the screen. The overlapped first polarized light may include a first polarized light and a converted first polarized light.

The first polarized light existing in the overlapped first polarized light and the converted first polarized light have almost no path error. The image 191b by the first polarized light and the image 195b by the second polarized light may be projected to the same size.

According to the technique according to the present specification, since the first polarized light and the converted first polarized light proceed in a superposed state, the sharpness due to the keystone phenomenon increases and the quality of the image can be enhanced.

4 is a diagram illustrating an exemplary stereoscopic imaging apparatus including one mirror.

The stereoscopic imaging apparatus may include at least one of a light splitter 110, a mirror 120, a mirror prism 130, a liquid layer 140, and / or a modulator 160.

The light splitter 110 can split the incident light (including the first polarized light and the second polarized light) into the first polarized light and the second polarized light based on the polarization direction, and convert the second polarized light into the first polarized light. The light splitter 110 may send the superimposed first polarized light to the mirror 120

The overlapped first polarized light may proceed in the direction toward the mirror 120 by the light splitter 110. [

The light splitter 110 may include a plurality of light splitter prisms 112 and a conversion module 117.

For example, in the case of a stereoscopic imaging device comprising a single mirror, the light splitter 110 may comprise a reflective prism 112.

The reflective prism 112 may pass the incident light (first polarized light and second polarized light) and the superimposed first polarized light reflected from the conversion module 117.

The conversion module 117 is disposed on the lower slope of the reflection prism 112 and can divide the incident light into first polarized light and second polarized light based on the polarization direction and convert the second polarized light into the first polarized light .

The reflective prism 112 may include a reflective prism emission surface 111 that emits the superimposed first polarized light reflected from the conversion module 117.

The mirror 120 may reflect the superimposed first polarized light including the first polarized light and the converted first polarized light to the screen.

The mirror prism 130 is disposed between the mirror 120 and the light splitter 110, and can pass the superimposed first polarized light.

For example, the mirror prism 130 may pass the superimposed first polarized light reflected from the light splitter 110.

For example, the mirror prism 130 may include at least one of a mirror prism receiving surface 132, a mirror prism inclined surface 134, and a mirror prism emitting surface 136.

The mirror prism receiving surface 132 may receive the overlapped first polarized light reflected from the light splitter 110. [

For example, the mirror prism receiving surface 132 may be in contact with and coupled to the light splitter 110. Specifically, the mirror prism receiving surface 132 can be brought into contact with the reflecting prism emitting surface 111 and coupled thereto.

In this case, errors in assembling the stereoscopic image device can be reduced, and the quality of the stereoscopic image projected on the screen can be improved.

The mirror prism inclined surface 134 emits the superimposed first polarized light reflected from the optical splitter 110 and passes through the mirror prism 130 and is reflected from the mirror 120 to be incident on the liquid layer 140 And can receive the nested first polarized light passing therethrough.

For example, the mirror prism inclined surface 134 may be inclined at a predetermined angle with respect to the mirror prism receiving surface 132.

The mirror prism emission surface 136 may emit the superimposed first polarized light that is reflected from the mirror 120 and passes through the liquid layer 140 and the mirror prism 130.

The liquid layer 140 occupies a space corresponding to the optical path of the superimposed first polarized light between the mirror and the light splitter, and can pass the superimposed first polarized light.

For example, a liquid layer 140 may be disposed between the mirror 120 and the mirror prism 130, and may be in contact with and coupled to the mirror 120 and the mirror prism 130.

The liquid layer may reduce the divergent angle of the superimposed first polarized light to correct the path of the superimposed first polarized light.

The technique disclosed herein can remove the air layer existing in the space between the conversion module 117 and the mirror 120. [ When the superimposed first polarized light passes through the air layer, the superimposed first polarized light emits in the air layer and loses energy.

However, the technique disclosed in this specification can reduce the angle of divergence of light and preserve the energy of light by removing the air layer in the space between the conversion module 117 and the mirror 120. [

For example, a mirror prism 130 and a reflection prism 112 may be disposed between the conversion module 117 and the mirror 120. Further, between the mirror 120 and the mirror prism 130, a liquid layer 140 may be disposed.

The overlapped first polarized light passing between the mirror 120 and the mirror prism 130 can conserve energy because the liquid layer 140 occupies a space between the mirror 120 and the mirror prism 130. [

When the mirror 120 moves or rotates, the liquid layer 140 may fluidly change its shape to occupy a space between the mirror 120 and the mirror prism 130.

The liquid layer 140 may comprise liquid having fluidity. The transmissivity of the liquid layer 140 may be the same as the transmissivity of the mirror prism 130. For example, the constituent components of the mirror prism 130 may be glass.

For example, the liquid layer 140 may comprise a liquid that is fluid and a transparent layer that surrounds the liquid. The transparent film can be brought into contact with and bonded to the mirror 120 and the mirror prism 130.

Alternatively, the liquid layer 140 may comprise a viscous, fluid liquid. Thus, the fluid liquid can fill the space between the mirror 120 and the mirror prism 130 without flowing between the mirror 120 and the mirror prism 130 due to viscosity.

Since the transmittance of the liquid layer 140 is equal to the transmittance of the mirror prism 130, the overlapped first polarized light can conserve energy while passing through the liquid layer 140.

In addition, the refractive index of the liquid layer 140 may be the same as or different from the refractive index of the mirror prism 130.

The stereoscopic image apparatus may further include a half-wave retarder (not shown) for converting light into another polarization component.

For example, the half-wave retarder can convert the superimposed first polarized light (S-polarized light) into superimposed second polarized light (P-polarized light). On the contrary, the half-wave retarder can convert the superimposed second polarized light (P-polarized light) into superimposed first polarized light (S-polarized light). Hereinafter, the former will be mainly described.

The half-wave retarder can be a half-wave retarder. Half-wave plates can be implemented with polymer films, quartz plates, or optically patterned static liquid crystal devices to account for geometric polarization variations.

The half-wave retarder may be disposed in the path of the superimposed first polarized light passing through the mirror prism emission surface 136.

Thus, the superimposed first polarized light reflected by the light splitter 110 can be converted to the superimposed second polarized light by the half-wave retarder and then directed to the screen.

The modulator 160 may selectively modulate the superimposed first polarized light into a first output polarized light that is synchronized with the image frame and corresponds to the left image frame or a second output polarized light that corresponds to the right image frame.

For example, the modulator 160 may change the polarization state of light by an electrical signal. The modulator 160 can modulate linearly polarized light into circularly polarized light.

The video projector may emit light including an image frame, and the image frame may include a left image frame and a right image frame. The image projector can alternately emit the left image frame and the right image frame in time. That is, the light incident on the stereoscopic image apparatus may include a left image frame or a right image frame alternately in time. Also, the left image frame and the right image frame may be alternated in time according to a predetermined frame rate. For example, the frame rate of the left image frame or the right image frame may be 24 frames / second, respectively.

The first output polarized light may correspond to the left image frame, and the second output polarized light may correspond to the right image frame. Further, the first output polarized light may correspond to one polarized light, and the second output polarized light may correspond to the second polarized light. Further, the first output polarized light and / or the second output polarized light may be polarized light different from the first polarized light and / or the second polarized light.

Since the input image frame is alternated with the left image frame and the right image frame, the modulator 160 can generate the first output polarized light and the second output polarized light synchronized with the input image frame.

For example, the user can view the first output polarized light corresponding to the left video frame as the left eye and the second output polarized light corresponding to the right video frame as the right eye using the polarizing glasses. As a result, the user can appreciate the three-dimensional stereoscopic image due to the parallax between the left image frame and the right image frame.

In addition, a lens (not shown) for magnifying and / or reducing the image may be disposed in the path of the superimposed first polarized light. For example, the lens may be disposed between the mirror prism 130 and the modulator 160, and may be disposed between the modulator 160 and the screen (not shown).

In addition, the mirror prism 130 can enlarge and / or reduce the size of the image due to the first polarized light reflected by the mirror 120.

5 is a diagram illustrating an exemplary stereoscopic imaging apparatus including two mirrors.

The stereoscopic image apparatus includes a light splitter 110, a first mirror 120a, a second mirror 120b, a first mirror prism 130a, a second mirror prism 130b, a first liquid layer 140a, A liquid layer 140b, and / or a modulator 160. In one embodiment,

The light splitter 110 can split the incident light (including the first polarized light and the second polarized light) into the first polarized light and the second polarized light based on the polarization direction, and convert the second polarized light into the first polarized light. The light splitter 110 may transmit the overlapped first polarized light to the first mirror 120a or the second mirror 120b.

The light splitter 110 may reflect some of the incident light to the first mirror 120a and reflect the remaining light to the second mirror 120b.

The light splitter 110 may include at least one of a first reflective prism 112a, a second reflective prism 112b, a first conversion module 117a, and / or a second conversion module 117b.

The first reflective prism 112a is disposed in the path of the light incident on the first conversion module 117a and is capable of receiving the incident light and emitting the overlapped first polarized light reflected from the first conversion module 117a have.

The second reflective prism 112b is disposed in the path of the light incident on the second conversion module 117b to receive the incident light and to emit the superimposed first polarized light reflected from the second conversion module 117b have.

The first conversion module 117a can reflect half the first polarized light to the first mirror 120a with respect to the vertical direction cross section of the incident light. Also, the first conversion module 117a can convert half of the second polarized light into the first polarized light and transmit it to the first mirror 120a.

The first conversion module 117a is disposed on the lower inclined surface of the first reflective prism 112a and can be brought into contact with the first reflective prism 112a.

The second conversion module 117b can reflect half the first polarized light to the second mirror 120b with respect to the vertical direction cross section of the incident light. In addition, the second conversion module 117b can convert half of the second polarized light into the first polarized light and transmit it to the second mirror 120b.

The second conversion module 117b is disposed on the lower inclined surface of the second reflective prism 112b and can be brought into contact with the second reflective prism 112b.

The superimposed first polarized light reflected by the first conversion module 117a may travel to the first mirror prism 130a, the first liquid layer 140a, and the first mirror 120a. The superimposed first polarized light reflected by the first mirror 120a may then proceed to the screen. Then, the superimposed first polarized light is modulated by the modulator 160 into the first output polarized light or the second output polarized light. The remedial contents are the same as the above.

The superimposed first polarized light reflected by the second conversion module 117b may proceed to the second mirror prism 130b, the second liquid layer 140b, and the second mirror 120b. The intercepted first polarized light reflected by the second mirror 120b may then proceed to the screen. The intercepted first polarized light is then modulated by the modulator 160 into a first output polarized light or a second output polarized light. The concrete contents are the same as the above.

In another embodiment, the half-wave retarder (not shown) may be arranged in the path of the superimposed first polarized light in the form of one or two half-wave retarders.

Accordingly, the superimposed first polarized light reflected by the light splitter 110 can be reflected by the first mirror 120a and the second mirror 120b and can be directed to the screen.

In another embodiment, the modulator 160 may be integral or divided.

In addition, a lens (not shown) for magnifying and / or reducing the image may be disposed in the path of the superimposed first polarized light. The first mirror prism 130a and / or the second mirror prism 130b may reflect the size of the image by the first polarized light reflected by the first mirror 120a and / or the second mirror 120b Enlarged and / or reduced.

Figure 6 is a comparison of an air layer and a liquid layer.

Referring to FIG. 1A, an air layer 140a is formed between the mirror 120a and the mirror prism 130a.

Particles 141a may be present in the air layer 140a. A difference occurs between the transmittance of the air layer 140a and the transmittance of the mirror prism 130a due to the particles 141a present in the air layer 140a. That is, the transmittance of the air layer 140a may be lower than that of the mirror prism 130a.

The superimposed first polarized light having passed through the mirror prism 130a passes through the air layer 140a and proceeds to the mirror 120a. In addition, the first polarized light reflected from the mirror 120a passes through the air layer 140a and proceeds to the mirror prism 130a.

In this case, the overlapped first polarized light passes through the air layer 140a twice. When the overlapped first polarized light passes through the air layer 140a, the first polarized light superimposed on the particles 141a existing in the air layer 140a may be struck. The superimposed first polarized light may be absorbed or reflected by the particles 141a present in the air layer 140a.

Thus, the energy of the superimposed first polarized light can be reduced by the air layer 140a. For example, a decrease in the energy of the superimposed first polarized light may include a change in the path of the unexpected light such as scattering, diffuse reflection, refraction, extinction, etc. of the light.

Referring to FIG. 1B, a liquid layer 140b is formed between the mirror 120b and the mirror prism 130b. The liquid layer 140b may be in contact with and coupled to the mirror 120b and the mirror prism 130b.

The transmittance of the liquid layer 140b may be the same as the transmittance of the mirror prism 130b. Also, the transmittance of the liquid layer 140b may be higher than the transmittance of the air layer 140a.

The liquid layer 140b may be composed of a transparent fluid liquid. In addition, the liquid in the liquid layer 140b may be surrounded by a transparent film. Also, the liquid layer can be composed of a viscous liquid without a transparent film.

In general, when light passes through a transparent medium (glass or water), the transparent medium does not absorb the energy of the light.

The superimposed first polarized light passing through the mirror prism 130b passes through the liquid layer 140b and proceeds to the mirror 120b. Further, the superimposed first polarized light reflected from the mirror 120b passes through the liquid layer 140b again and proceeds to the mirror prism 130b.

In this case, the overlapped first polarized light passes through the liquid layer 140b twice. However, even if the superimposed first polarized light passes through the liquid layer 140b, the energy of the superimposed first polarized light can be preserved as it is because the liquid layer 140b does not absorb and / or reflect the superimposed first polarized light.

Therefore, the technique disclosed in this specification can provide an effect of improving the image quality and the final brightness of the stereoscopic image projected on the screen, compared with the prior art.

7 is a diagram illustrating an exemplary mirror module.

Referring to Figure (a), the mirror module may include a mirror 120, a mirror prism 130, and a liquid layer 140.

The mirror 120 can move. For example, the mirror 120 can move in the x-axis direction (the direction toward the screen) or the y-axis direction (the direction perpendicular to the x-axis direction). In addition, the mirror 120 can rotate about any z-axis 123 on the mirror 120.

The superimposed first polarized light reflected by the light splitter is reflected by the mirror 120 in the screen direction. Since the superimposed first polarized light includes the first polarized light and the converted first polarized light, the first polarized light and the converted first polarized light can overlap each other on the screen to form a brighter image.

At this time, the mirror 120 can be adjusted so that the image of the superimposed first polarized light can be properly projected on the screen.

The liquid layer 140 may provide a space through which the mirror 120 can move.

The liquid layer 140 may be disposed between the mirror 120 and the mirror prism 130 and may be in contact with and coupled to the mirror 120 and the mirror prism 130.

Since the liquid layer 140 has fluidity, it is possible to provide a space that allows the movement of the mirror 120 when the mirror 120 moves in the x-axis direction or the y-axis direction or rotates about the z-axis have.

The liquid layer 140 may also be formed to fill a space between the mirror 120 and the mirror prism 130 corresponding to the optical path of the first polarized light reflected by the light splitter in a state in which the mirror 120 is moved . The liquid layer 140 may prevent the air layer from being generated in the space between the mirror 120 and the mirror prism 130.

As a result, the superimposed first polarized light reflected by the light splitter can pass through the liquid layer 140 and conserve energy.

Referring to Figures (b) and (c), the mirror 120 is shown rotated.

The mirror 120 can reflect the superimposed first polarized light 5 reflected from the light splitter in the screen direction. At this time, the mirror 120 can adjust the angle so that the first polarized light 5, which is superimposed while being rotated or moved, can form an image on the screen. That is, the mirror 120 can adjust the angle of the superimposed first polarized light 5 so that the image by the superimposed first polarized light 5 can be projected correctly on the screen.

The liquid layer 140 provides a space through which the mirror 120 can move. The liquid layer 140 can fill the space between the mirror 120 and the mirror prism 130, which corresponds to the optical path of the first polarized light superposed, even when the mirror 120 is moved.

8 is a view showing an example of using an exemplary stereoscopic image apparatus including one mirror.

The video projector 101 may emit light including an image frame. The image frame may include a left image frame and a right image frame. The video projector 101 can alternately emit the left video frame and the right video frame temporally. That is, the light incident on the stereoscopic image apparatus may include a left image frame or a right image frame alternately in time.

The light may comprise a first polarized light and a second polarized light. When the left image frame is included in the light, the light may include the first polarized light and the second polarized light corresponding to the left image frame. In addition, when the right image frame is included in the light, the light may include first and second polarized lights corresponding to the right image frame.

The first polarized light may be reflected by the light splitter 110 and travel in the direction of the mirror 120. The second polarized light is converted into the first polarized light by the light splitter 110, and can proceed in the direction of the mirror 120.

The light splitter 110 may reflect all of the first polarized light that has been superimposed on one mirror 120.

The superimposed first polarized light reflected by the optical splitter 110 may be reflected by the mirror 120 and travel in the screen direction. Since the transmittance of the liquid layer 140 is equal to the transmittance of the mirror prism 130 and the air layer between the mirror 120 and the optical splitter 110 is removed by the liquid layer 140 and the mirror prism 130, The overlapped first polarized light can conserve energy even though it passes through the liquid layer 140 and the mirror prism 130. [

The mirror 120 can adjust the reflection angle of the superimposed first polarized light so that the image by the superimposed first polarized light can be projected on the screen properly.

The modulator 160 may modulate the superimposed first polarized light into a first output polarization or a second output frame that is synchronized with the image frame.

In addition, a lens (not shown) for magnifying and / or reducing the image may be disposed in the path of the superimposed first polarized light. In addition, the mirror prism 130 can enlarge and / or reduce the size of the image due to the first polarized light reflected by the mirror 120.

The first output polarized light may correspond to the left image frame, and the second output polarized light may correspond to the right image frame.

The first output polarized light and the second output polarized light may form an image on the screen 190 in synchronization with the image frame.

9 is a view showing an example of using an exemplary stereoscopic image apparatus including two mirrors.

The stereoscopic image apparatus includes at least one of a light splitter 110, a first mirror 120a, a second mirror 120b, a first mirror prism 130a, a second mirror prism 130b, and / or a modulator 160 . ≪ / RTI >

The light splitter 110 can split the incident light (including the first polarized light and the second polarized light) into the first polarized light and the second polarized light based on the polarization direction, and convert the second polarized light into the first polarized light. The light splitter 110 may transmit the overlapped first polarized light to the first mirror 120a or the second mirror 120b.

The first mirror 120a may reflect the superimposed first polarized light reflected from the light splitter in the direction of the screen 190. [

The second mirror 120b may reflect the remaining superimposed first polarized light reflected from the light splitter in the direction of the screen 190. [

The modulator 160 can modulate the superimposed first polarized light. The modulator 160 may be integral or may be divided into two.

The modulator 160 may modulate the superimposed first polarized light into a first output polarized light that is synchronized with the image frame and corresponds to the left image frame or a second output polarized light that corresponds to the right image frame.

In addition, a lens (not shown) for magnifying and / or reducing the image may be disposed in the path of the superimposed first polarized light. The first mirror prism 130a and / or the second mirror prism 130b may reflect the size of the image by the first polarized light reflected by the first mirror 120a and / or the second mirror 120b Enlarged and / or reduced.

As a result, the left image or the right image may alternatively be output to the screen 190.

10 is a diagram illustrating an exemplary stereoscopic imaging apparatus including one mirror.

The stereoscopic imaging apparatus may include at least one of a light splitter 110, a mirror 120, a mirror prism 130, a liquid layer 140, and / or a modulator 160. The specific contents of the stereoscopic image apparatus may include all of the above-mentioned contents. Hereinafter, the differences will be mainly described.

The mirror 120 and the mirror prism 130 can be brought into contact with each other. For example, the mirror 120 and the mirror prism inclined surface 134 of the mirror prism 130 can be brought into contact with each other.

The combined mirror 120 and mirror prism 130 can move simultaneously. For example, the combined mirror 120 and the mirror prism 130 are arranged in the y-axis direction (the direction in which the superimposed first polarized light reflected from the light splitter faces the mirror) or the x-axis direction The direction in which the polarized light is directed to the screen).

In addition, the combined mirror 120 and the mirror prism can rotate about any axis (z-axis) on the mirror 120 or the mirror prism 130.

The liquid layer 140 may be disposed between the mirror prism 130 and the light splitter 110 and may be in contact with and coupled to the mirror prism 130 and the light splitter 110. Specifically, the liquid layer 140 is disposed between the mirror prism receiving surface 132 and the reflecting prism emitting surface 111, and can be brought into contact with the mirror prism receiving surface 132 and the reflecting prism emitting surface 111 have.

Accordingly, the first polarized light reflected from the light splitter 110 can be sequentially transmitted through the liquid layer 140 and the mirror prism 130 to the mirror 120.

The liquid layer 140 may remove the air layer existing in the space between the mirror prism 130 and the light splitter 110. The liquid layer 140 may reduce the divergent angle of the first polarized light to correct the path of the first polarized light. The overlapped first polarized light passing between the mirror 120 and the mirror prism 130 can conserve energy because the liquid layer 140 occupies a space between the mirror 120 and the mirror prism 130. [

In addition, the liquid layer 140 may provide a space through which the combined mirror 120 and the mirror prism 130 can move. As a result, the combined mirror 120 and mirror prism 130 can adjust the angle of reflection of the superimposed first polarized light so that the image due to the superimposed first polarized light can be projected correctly on the screen.

In addition, a lens (not shown) for magnifying and / or reducing the image may be disposed in the path of the superimposed first polarized light. In addition, the mirror prism 130 can enlarge and / or reduce the size of the image due to the first polarized light reflected by the mirror 120.

11 is a diagram illustrating an exemplary stereoscopic imaging apparatus including two mirrors.

The stereoscopic image apparatus includes a light splitter 110, a first mirror 120a, a second mirror 120b, a first mirror prism 130a, a second mirror prism 130b, a first liquid layer 140a, A liquid layer 140b, and / or a modulator 160. In one embodiment, The specific contents of the stereoscopic image apparatus may include all of the above-mentioned contents. Hereinafter, the differences will be mainly described.

The first mirror 120a and the first mirror prism 130a may be in contact with each other. For example, the first mirror 120a and the first mirror prism inclined surface 134a of the first mirror prism 130a can be brought into contact with each other.

The contents of the combined first mirror 120a and the first mirror prism 130a may include both the above-mentioned combined mirror and mirror prism.

The second mirror 120b and the second mirror prism 130b may be in contact with each other. For example, the b-th mirror prism inclined surface 134b of the b-th mirror prism 130b and the b-th mirror 120b may be in contact with each other.

The contents of the combined second mirror 120b and second mirror prism 130b may include both the above-described combined mirror and mirror prism.

The first liquid layer 140a may be disposed between the first mirror prism 130a and the light splitter 110 and may be in contact with and coupled to the first mirror prism 130a and the light splitter 110. [ Specifically, the first liquid layer 140a is disposed between the first mirror prism receiving surface 132a and the first reflecting prism emitting surface 111a, and includes a first mirror prism receiving surface 132a and a first reflecting prism emitting surface 111a. And can be brought into contact with the surface 111a.

The second liquid layer 140b may be disposed between the second mirror prism 130b and the light splitter 110 and may be in contact with and coupled to the second mirror prism 130b and the light splitter 110. [ Specifically, the second liquid layer 140b is disposed between the second mirror prism receiving surface 132b and the second reflecting prism emitting surface 111b, and the second mirror prism receiving surface 132b and the second reflecting prism emitting surface 111b. And can be brought into contact with the surface 111b.

The contents of the first liquid layer 140a and the second liquid layer 140b may include all of the contents of the liquid layer described above.

In addition, a lens (not shown) for magnifying and / or reducing the image may be disposed in the path of the superimposed first polarized light.

Further, it is preferable that a path of the first polarized light reflected by the first mirror 120a and / or the second mirror 120b and passing through the first mirror prism 130a and / or the second mirror prism 130b A lens (not shown) for enlarging and / or reducing an image may be additionally disposed.

12 is a diagram illustrating an exemplary stereoscopic imaging apparatus including one mirror.

The stereoscopic imaging apparatus may include at least one of a light splitter 110, a mirror 120, a mirror prism 130, a liquid layer 140, and / or a modulator 160. The specific contents of the stereoscopic image apparatus may include all of the above-mentioned contents. Hereinafter, the differences will be mainly described.

Each mirror 120 and / or mirror prism 130 may be individually movable. For example, each of the mirrors 120 and / or the mirror prism 130 may be disposed in the y-axis direction (the direction in which the superimposed first polarized light reflected by the light splitter faces the mirror) or the x- The direction in which the first polarized light is directed to the screen).

In addition, each mirror 120 and / or mirror prism 130 may rotate about any axis (z axis) on the mirror 120 and / or the mirror prism 130.

The liquid layer 140 may include a lower liquid layer 141 and an upper liquid layer 143.

The lower liquid layer 141 may be disposed between the mirror prism 130 and the light splitter 110 and may be in contact with and coupled to the mirror prism 130 and the light splitter 110.

The upper liquid layer 143 is disposed between the mirror 120 and the mirror prism 130 and may be contacted and coupled to the mirror 120 and the mirror prism 130.

The lower liquid layer 141 and / or the upper liquid layer 143 may be formed by removing the air layer present in the space between the mirror 120 and the light splitter 110, reducing the divergence angle of the superimposed first polarized light, The path of the first polarized light can be corrected.

In addition, the lower liquid layer 141 and / or the upper liquid layer 143 may provide a space through which the respective mirror 120 and / or the mirror prism 130 may move.

In addition, a lens (not shown) for magnifying and / or reducing the image may be disposed in the path of the superimposed first polarized light. In addition, a lens (not shown) for magnifying and / or reducing the image may be additionally disposed in the path of the first polarized light reflected by the mirror 120 and passed through the mirror prism 130.

13 is a diagram illustrating an exemplary stereoscopic imaging apparatus including two mirrors.

The stereoscopic image apparatus includes a light splitter 110, a first mirror 120a, a second mirror 120b, a first mirror prism 130a, a second mirror prism 130b, a first liquid layer 140a, A liquid layer 140b, and / or a modulator 160. In one embodiment, The specific contents of the stereoscopic image apparatus may include all of the above-mentioned contents. Hereinafter, the differences will be mainly described.

The first liquid layer 140a may include a first lower liquid layer 141a and a first upper liquid layer 143a.

The first lower liquid layer 141a may be disposed between the first mirror prism 130a and the light splitter 110 and may be in contact with and coupled to the first mirror prism 130a and the light splitter 110. [ Specifically, the first lower liquid layer 141a is disposed between the first mirror prism receiving surface 132a and the first reflecting prism emitting surface 111a, and has a first mirror prism receiving surface 132a and a first reflecting prism emitting surface 111a. And can be brought into contact with the emission surface 111a.

The first upper liquid layer 143a is disposed between the first mirror 120a and the first mirror prism 130a and may be in contact with and coupled to the first mirror 120a and the first mirror prism 130a. Specifically, the first upper liquid layer 143a is disposed between the first mirror 120a and the first mirror prism inclined surface 134a and is in contact with the first mirror 120a and the first mirror prism inclined surface 134a Can be combined.

The second liquid layer 140b may include a second lower liquid layer 141b and a second upper liquid layer 143b.

The second lower liquid layer 141b may be disposed between the second mirror prism 130b and the light splitter 110 and may be in contact with and coupled to the second mirror prism 130b and the light splitter 110. [ Specifically, the second lower liquid layer 141b is disposed between the second mirror prism receiving surface 132b and the second reflecting prism emitting surface 111b, and the second mirror prism receiving surface 132b and the second reflecting prism emitting surface 111b, And can be brought into contact with the emission surface 111b.

The second upper liquid layer 143b may be disposed between the second mirror 120b and the second mirror prism 130b and may be in contact with and coupled to the second mirror 120b and the second mirror prism 130b. Specifically, the second upper liquid layer 143b is disposed between the second mirror 120b and the second mirror prism inclined surface 134b and is in contact with the second mirror 120b and the second mirror prism inclined surface 134b Can be combined.

The first liquid layer 140a and / or the second liquid layer 140b may be formed by removing the air layer present in the space between the mirror and the light splitter, reducing the divergence angle of the superimposed first polarized light, The path can be corrected.

In addition, the first liquid layer 140a and / or the second liquid layer 140b may provide a space through which each mirror and / or mirror prism may move.

In addition, a lens (not shown) for magnifying and / or reducing the image may be disposed in the path of the superimposed first polarized light.

Further, it is preferable that a path of the first polarized light reflected by the first mirror 120a and / or the second mirror 120b and passing through the first mirror prism 130a and / or the second mirror prism 130b A lens (not shown) for enlarging and / or reducing an image may be additionally disposed.

The contents of the first liquid layer 140a and the second liquid layer 140b may include all of the contents of the liquid layer described above.

In the foregoing, preferred embodiments of the present invention have been described with reference to the accompanying drawings. Herein, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and should be construed as meaning and concept consistent with the technical idea of the present technology.

The scope of the present technology is not limited to the embodiments disclosed in the present specification, and the present invention may be modified, changed, or improved in various forms within the scope of the present invention.

110: optical splitter 120: mirror
160: modulator

Claims (10)

A first polarized light beam splitter for splitting incident light into first polarized light and second polarized light on the basis of the polarization direction and converting the second polarized light into the first polarized light and outputting the polarized light in which the first polarized light and the converted first polarized light are superimposed A light splitter;
A mirror for reflecting the superimposed polarized light including the first polarized light and the converted first polarized light to a screen;
A mirror prism disposed between the mirror and the light splitter such that one side faces a reflecting surface of the mirror and passes the superimposed first polarized light emitted from the light splitter toward the mirror without polarization conversion; And
And a liquid layer disposed between and in contact with the mirror and the mirror prism between the mirror and the mirror prism,
Wherein the mirror is set to be able to rotate or move the mirror within an angle until the mirror is in contact with the mirror prism in a fixed form of the reflecting surface, and the liquid layer is set so that the shape changes according to the rotation of the mirror Stereoscopic imaging device. The method according to claim 1,
Wherein the light splitter comprises a conversion module,
And a polarized light splitting part for reflecting the first polarized light and passing the second polarized light. 3. The method of claim 2,
The optical splitter comprises:
And a phase shifting unit for shifting the passed second polarized light by a quarter wavelength. The method of claim 3,
The optical splitter comprises:
And a beam splitter mirror for reflecting the second polarized light phase-shifted by the 1/4 wavelength through the phase shifting unit to the mirror. 5. The method of claim 4,
The phase shifter further phase-shifts the second polarized light shifted by the 1/4 wavelength reflected from the optical splitter mirror by a quarter wavelength,
And the second polarized light further phase shifted by a quarter wavelength is the converted first polarized light. delete delete The method according to claim 1,
Wherein a transmittance of the liquid layer is equal to a transmittance of the mirror prism. delete The method according to claim 1,
Further comprising a second liquid layer disposed between and in contact with the mirror prism and the light splitter between the mirror prism and the light splitter,
Wherein the mirror prism is set so as to be able to rotate or move the mirror prism within an angle up to the contact with the light splitter, and the second liquid layer is configured to change its shape in accordance with rotation of the mirror prism.

Images