KR101773126B1 - Stereoscopic projection apparatus and linearly polarized light modulating apparatus for stereoscopic projection - Google Patents

Abstract

The present invention provides a stereoscopic projection apparatus enabling a viewer to watch a stereoscopic image, easily installing and moving the projector, and reducing the influence of vibration. To this end, the stereoscopic projection apparatus includes a projection unit for projecting an image, a linear polarization plate which is arranged to pass light emitted from the projection unit and has a polarization axis in one direction, an electronic optical shutter which is arranged to transmit the light having passed through the linear polarization plate and alternatively switches a first state with a phase retardation axis forming a first angle with a linear polarization direction of the light having passed through the linear polarization plate and a second state with a phase retardation axis forming a second angle with the linear polarization direction of the light passing through the linear polarization plate, and a reverse dispersion film arranged to transmit the light having passed through the electronic optical filter.

Description

[0001] STEREOSCOPIC PROJECTION APPARATUS AND LINEARLY POLARIZED LIGHT MODULATING APPARATUS FOR STEREOSCOPIC PROJECTION [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a stereoscopic projection apparatus and a stereoscopic image-using linear polarization light modulating apparatus, and more particularly, to a stereoscopic projection apparatus and stereoscopic image-using linear polarization light modulation apparatus for enabling stereoscopic image viewing with a projector.

There are various methods for implementing the stereoscopic image, but a film type pattern polarizing mechanism capable of realizing a three-dimensional image at a relatively low cost for a stereoscopic projection is generally used.

1 is a conceptual diagram schematically showing a conventional stereoscopic projection apparatus. In particular, the stereoscopic projection apparatus shown in Fig. 1 can be constituted by the projector 1, the linear polarizer 2, the screen 3 and the linearly polarized glasses 4.

Specifically, when the two projectors 1a and 1b output the left eye image and the right eye image, the left eye image is linearly polarized by the linearly polarizing plate 2a having a polarization axis in one direction, and the right eye image is orthogonal to the one direction Polarized light by the linear polarizer 2b having a polarization axis in the direction of the screen 3 and then reflected by the screen 3 and displayed to the user through the linearly polarized glasses 4. [ The left eye lens of the linearly polarizing glasses 4 is provided with a linear polarizer 4L having the same polarization axis as the linear polarizer (for example, 2a) through which the left eye image has passed, so that the right eye image can not be displayed on the left eye of the user. Similarly, the right eye lens of the linearly polarized glasses 4 is provided with a linear polarizer 4R having the same polarization axis as the linear polarizer (for example, 2b) through which the right-eye image has passed, so that the left eye image can not be displayed on the right eye of the user have.

At this time, since the conventional stereoscopic projection apparatus uses two projectors 1a and 1b, there is a problem that a double image or a 3D ghost phenomenon occurs when the left eye image and the right eye image do not exactly coincide with each other on the screen 3 there was. In addition, since the two projectors 1a and 1b must be installed so that the left eye image and the right eye image coincide exactly on the screen 3, it is necessary to increase the cost and time required for installation and movement, There was a problem.

Korean Patent Laid-Open No. 10-2010-0119477

Embodiments of the present invention provide stereoscopic projection apparatuses and stereoscopic zero-use linearly polarized light modulation apparatuses that enable stereoscopic image viewing with one projector, ease of installation and movement of the projector, and reduction of influence due to vibration.

According to an embodiment of the present invention, there is provided a projection apparatus comprising: a projection unit capable of projecting an image; A linear polarizer having a polarization axis in one direction arranged to allow light emitted from the projection unit to pass therethrough; And a phase retardation axis arranged to pass the light passing through the linear polarizer and passing through the linear polarizer and forming a first angle with a linear polarization direction of light passing through the linear polarizer, And a second state having a phase delay axis constituting the phase delay axis; And a reverse dispersion film disposed so that light passing through the electron optical shutter passes therethrough.

According to a further feature of the invention, the amount of phase delay in time, the inverse dispersion film to be referred to as the magnitude of the phase retardation R _cell in the electronic optical shutter can be calculated by dividing the R _cell of any one of natural numbers have.

According to still another aspect of the present invention, when the length of an elliptically polarizing long axis of light passing through the electron optical shutter is a, the length of an elliptical polarization short axis of light passing through the electron optical shutter is b, and the wavelength of light passing through the electron optical shutter is λ , When a is equal to or larger than a value obtained by multiplying b by the linear polarization standard ratio, the magnitude of the phase delay in the reverse dispersion film may be? / 2.

According to still another aspect of the present invention, when the length of an elliptically polarizing long axis of light passing through the electron optical shutter is a, the length of an elliptical polarization short axis of light passing through the electron optical shutter is b, and the wavelength of light passing through the electron optical shutter is λ , When a is less than a value obtained by multiplying b by the circular polarization reference ratio, the magnitude of the phase delay in the reverse dispersion film may be? / 4.

According to another embodiment of the present invention, there is provided a projection apparatus including: a projection unit capable of projecting an image; A linear polarizer having a polarization axis in one direction arranged to allow light emitted from the projection unit to pass therethrough; A first state having a phase retardation axis disposed so as to allow light passing through the linear polarizer to pass therethrough and having a first angle with a linear polarization direction of light passing through the linear polarizer, and a second state having a second angle with the linear polarization direction of light passing through the linear polarizer An electron optical shutter for alternately switching a second state having a phase delay axis to be formed; And one of the left eye lens and the right eye lens of the stereoscopic glasses is placed in the same direction as the direction of the elliptical polarization long axis of the light passing through the electro-optical shutter of the first state, And the other of the left eye lens and the right eye lens of the stereoscopic glasses uses a line having a polarization axis in the same direction as the direction of the elliptical polarization long axis of the light having passed through the electro- Wherein the left and right eye lenses of the stereoscopic glasses are further provided with a reverse dispersion film disposed so that light passes through before entering the linear polarizer of the stereoscopic glasses. Thereby starting the projection apparatus.

According to another embodiment of the present invention, there is provided a liquid crystal display comprising: a linear polarizer having a polarization axis in one direction; A first state having a phase retardation axis disposed so as to allow light passing through the linear polarizer to pass therethrough and having a first angle with a linear polarization direction of light passing through the linear polarizer, and a second state having a second angle with the linear polarization direction of light passing through the linear polarizer An electron optical shutter for alternately switching a second state having a phase delay axis to be formed; And a reverse dispersion film disposed so as to allow light passing through the electron optical shutter to pass therethrough.

The stereoscopic projection apparatus and stereoscopic image using linearly polarizing light modulating apparatus according to embodiments of the present invention enable stereoscopic image viewing with one projector, ease of installation of the projector, ease of movement, and reduction of influence due to vibration.

1 is a conceptual diagram schematically showing a conventional stereoscopic projection apparatus.
2 is a conceptual diagram schematically showing a linearly polarized light modulating apparatus according to an embodiment of the present invention.
3 is a conceptual diagram schematically showing a stereoscopic projection apparatus according to an embodiment of the present invention.
4 is a conceptual diagram schematically showing a three-dimensional linear polarized light modulating apparatus according to an embodiment of the present invention.
5 is a conceptual diagram schematically showing a stereoscopic projection apparatus according to another embodiment of the present invention.
6 is a conceptual diagram schematically showing the polarization state of light for explaining the operation of the stereoscopic projection apparatus shown in Fig.
7 is a conceptual diagram schematically showing a stereoscopic projection apparatus according to another embodiment of the present invention.
8 is a view schematically showing wavelength dispersion according to another embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. The effects and features of the present invention and methods of achieving them will be apparent with reference to the embodiments described in detail below with reference to the drawings. However, the present invention is not limited to the embodiments described below, but may be implemented in various forms. In the following embodiments, the terms first, second, and the like are used for the purpose of distinguishing one element from another element, not the limitative meaning. Also, the singular expressions include plural expressions unless the context clearly dictates otherwise. Also, the terms including, comprising, or having are intended to mean that a feature or element described in the specification is present and does not preclude the possibility that one or more other features or components may be added. Also, in the drawings, for convenience of explanation, the components may be exaggerated or reduced in size. For example, the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of explanation, and thus the present invention is not necessarily limited to those shown in the drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, wherein like reference numerals refer to like or corresponding components throughout the drawings, and a duplicate description thereof will be omitted .

2 is a conceptual diagram schematically showing a linearly polarized light modulating apparatus according to an embodiment of the present invention.

2, the linearly polarized light modulator according to the present embodiment is provided with an electronic light shutter (ELS) for polarizing the light _(LI ℓ, ℓ _RI) polarizing the light _(I ℓ) emitted from youngsabu.

Light _(I ℓ) emitted from youngsabu is an image having a plurality of frames, and each frame contains a frame image (f _L) and a right-eye image frame for (f _R) for the left eye.

The electro-optical shutter ELS forms different phase delay axes according to the timings at which the left and right eye image frames f _L and f _R are projected at the projection part, so that the left eye image frame f _L and polarized light (ℓ _LI) polarization of the left-eye image, the image frame (f _R) for the right eye is thereby polarized in the polarization light (ℓ _RI) of the right-eye image.

By thus polarizing the time-divided three-dimensional image using the linearly polarized light modulating apparatus according to the present embodiment, the stereoscopic image can be displayed through the linearly polarized eyeglasses to which the shutter glass is not applied.

3 is a conceptual diagram schematically showing a stereoscopic projection apparatus according to an embodiment of the present invention.

3, the stereoscopic projection apparatus according to the present embodiment includes a projection unit 100, a linear polarization light modulator 200, a screen 300, and linearly polarized glasses 400.

The projection unit 100 can project an image. The projection unit 100 may project the left eye image to be recognized in the left eye of the user and the right eye image to be recognized in the right eye of the user in a time division manner. For example, the projection unit 110 can project the left-eye image 1 frame and the right-eye image 1 frame alternately. The image may be a predetermined constant image at any time, or may be modified into various images depending on the situation.

The linear polarization light modulator 200 may include a linear polarizer 205 and an electro-optical shutter 210.

The linear polarizer 205 is disposed so as to allow light emitted from the projection unit 100 to pass therethrough and may have a polarization axis in one direction. The light emitted from the projection unit 100 passes through the linear polarizer 205 and can be linearly polarized in the direction of the polarization axis of the linear polarizer 205.

Alternatively, the projection unit 100 may include a linear polarizer (not shown) to project a linearly polarized image in one direction. Of course, if the projection unit 100 includes a backlight (not shown), the backlight may cause the projection unit 100 to project a linearly polarized image in one direction naturally by emitting linearly polarized light in one direction. In this case, the linear polarizer 205 in the linear polarization light modulator 200 can be omitted.

The electro-optical shutter 210 includes a liquid crystal cell through which the linearly polarized light passes and passes through the linear polarizer 205 and is capable of being supplied with power. The liquid crystal cell is driven according to the power applied to the liquid crystal cell. The phase of the transmitted light can be delayed or the brightness of the transmitted light can be adjusted. At this time, the electro-optical shutter 210 has a first state having a phase retardation axis that forms a first angle with the linearly polarized light direction of the light that has passed through the linear polarizer 205 using an AC power source, A second state having a phase delay axis that forms a second angle with the linearly polarized light direction can be alternately switched. Here, the first angle and the second angle may be vertical.

When the projection unit 100 projects an image in time division, the electro-optical shutter 210 can apply a power supply signal in accordance with the projection timings of the left-eye image and the right-eye image. In this case, either one of the left eye image and the right eye image is first elliptically polarized by a phase delay according to the phase delay axis of the first state, and the other one of the left eye image and the right eye image is phase- Can be delayed and become second elliptically polarized. In the description of the present embodiment, the first elliptically polarized light is referred to as x-polarized light for convenience, and the second elliptically polarized light is referred to as y-polarized light. The x-polarized light corresponds to the left eye image of the projection unit 100, and the y-polarized light corresponds to the right eye image of the projection unit 100. Alternatively, the x-polarized light may correspond to the right eye image of the projection unit 100 and the y-polarized light may correspond to the left eye image region 114 of the projection unit 100, And variants illustrate the case where x-polarized light corresponds to the left eye image of the projection unit 100 for convenience and y-polarized light corresponds to the right eye image of the projection unit 100.

As shown in FIG. 3, a component including the projection unit 100 and the linearly polarizing light modulating device 200 may be referred to as a stereoscopic projection apparatus. Of course, FIG. 2 also shows the linear polarized light glasses 400 to be worn by the user, and the components including the projection unit 100, the linear polarized light modulating device 200 and the linearly polarized light glasses 400 shown in FIG. Device. 2 also shows a screen 300 on which an image projected through the projection unit 100 is reflected and includes the projection unit 100, the linearly polarized light modulation device 200, the screen 300, The constituent elements including the linearly polarized glasses 400 may be referred to as a stereoscopic projection apparatus. In the description of this embodiment, constituent elements including only the projection unit 100 and the linear polarization light modulation device 200 are referred to as a stereoscopic projection apparatus.

The screen 300 has a reflecting surface for projecting from the front surface or a projection surface for projecting from front and rear surfaces. In the case of the reflective surface, x-polarized light or y-polarized light that has passed through the linearly polarized light modulating device 200 can be reflected from the reflecting surface to reach the linearly polarized glasses 400 located on the front surface of the screen 300, In the case of a slope, x-polarized light or y-polarized light may form an image on the projection surface and reach the linearly polarized glasses 400 located on the front and rear sides of the screen 300. A screen with a low loss of silver or aluminum may be used as the reflective surface, and a screen having high transparency of acrylic material may be used for the projection surface.

The linearly polarized glasses 400 have a left eye lens and a right eye lens. As described above, it is assumed that the x-polarized light corresponds to the left eye image and the y-polarized light corresponds to the right eye image. Thus, the left eye lens of the linearly polarized glasses 400 allows the x-polarized light to be incident , And the right eye lens of the linearly polarized glasses 400 allows y-polarized light to be incident. Therefore, hereinafter, the case where the left eye lens of the linearly polarized glasses 400 corresponds to the x-polarized light for convenience and the right eye lens of the linearly polarized glasses 400 corresponds to the y-polarized light will be described. However, it goes without saying that the relationship may be changed if the x-polarized light and the y-polarized light do not correspond to the left eye image and the right eye image of the projection unit 100, respectively.

The left eye lens includes a linearly polarizing plate 410L having a polarization axis in the same direction as the elliptically polarizing long axis direction of the x-polarized light, arranged so as to pass the light passing through the electron optical shutter 210. [ The right eye lens has a linearly polarizing plate 410R having a polarization axis in the same direction as the elliptically polarizing long axis direction of y-polarized light. Here, the elliptically polarized long axis direction of the x polarized light and the elliptically polarized long axis direction of the y polarized light may be vertical.

4 is a conceptual diagram schematically showing a three-dimensional linear polarized light modulator 200 according to an embodiment of the present invention.

Referring to FIG. 4, the three-dimensional linear polarizing light modulator 200 according to the present embodiment includes a linear polarizer 205, an electro-optical shutter 210, and a back-scattering film 220.

In the linear polarizer 205, the linear polarizer 205 is disposed so as to allow light emitted from the projection unit to pass therethrough, and may have a polarization axis in one direction. The light emitted from the projection unit can be linearly polarized in the direction of the polarization axis of the linearly polarizing plate 205 while passing through the linearly polarizing plate 205.

The electron optical shutter 210 includes a liquid crystal cell through which the linearly polarized light passes and passes through the linear polarizer 205 and is capable of applying a power source 211 to the power source 211 The phase of the light passing through the liquid crystal cell can be delayed or the brightness of the transmitted light can be controlled. At this time, the electro-optical shutter 210 has a first state having a phase retardation axis that forms a first angle with the linearly polarized light direction of the light that has passed through the linear polarizer 205 using an AC power source, A second state having a phase delay axis that forms a second angle with the linearly polarized light direction can be alternately switched.

The electro-optical shutter 210 may include a liquid crystal cell and may have wavelength dispersion characteristics as indicated by reference numeral 212. (For example, blue light having a wavelength of 475 nm) having relatively long wavelengths pass through the electro-optical shutter 210 and light having relatively long wavelengths When passing through the electron optical shutter 210, there is a large difference in the degree of phase delay. Accordingly, even when light having a long wavelength (for example, red light and green light) emitted from the projection unit passes through the electro-optical shutter 210, the light becomes polarized near the linearly polarized light, while light having a relatively short wavelength (for example, Blue light having a wavelength) becomes polarized closer to circularly polarized light. That is, the polarized state of the blue light emitted from the projection unit and passing through the electro-optical shutter 210 is different from the polarized state of the red light and the green light emitted from the projection unit and passing through the electro-optical shutter 210.

For example, when the left eye image passes through the electro-optical shutter 210, the long wavelength light (for example, red light and green light) included in the left eye image becomes polarized light close to the linearly polarized light, The right eye lens of the linearly polarized eyeglasses provided with the linearly polarizing plate in the direction perpendicular to the linearly polarized light direction does not pass through. On the other hand, a light having a short wavelength (for example, blue light) included in the left eye image is polarized close to circularly polarized light, and passes through both the left eye lens and the right eye lens of the linearly polarized eyeglasses to display a part of the left eye image on the right eye .

In order to prevent such a problem, the three-dimensional linear polarizing light modulator 200 according to the present embodiment further includes a reverse dispersion film 220 in the linear polarizer 205 and the electro-optical shutter 210 of FIG.

The back-scattering film 220 is arranged to pass the phase retarded light passing through the electro-optical shutter 210 and may have a reverse dispersion property 222 for correcting the wavelength dispersion property 212 of the liquid crystal cell.

Here, when the magnitude of the phase delay in the liquid crystal cell without the power supply 211 is _Rcell , the magnitude of the phase delay in the back-scattered film 220 can be set to be _Rcell / n . In this case, n is a natural number.

When the light passing through the electron optical shutter 210 becomes polarized light close to linearly polarized light, when the wavelength of the light is?, The phase delay in the back-scattered film 220 is set to be? / 2 . Here, when a is equal to or larger than a value obtained by multiplying b by the linear polarization standard ratio, when the length of the elliptical polarization long axis is a and the length of the elliptical polarization short axis is b, with respect to light passing through the electro-optical shutter 210, It can be considered that the polarized light is near.

When the light passing through the electron optical shutter 210 is polarized near the circularly polarized light, when the wavelength of the light is?, The phase delay in the back-scattered film 220 is set to be? / 2 . Here, when the length of the elliptical polarization long axis is a and the length of the elliptical polarization short axis is b, with respect to the light having passed through the electro-optical shutter 210, if a is less than a value obtained by multiplying the circular polarization standard ratio by b, It can be seen that the polarized light is close to the polarized light.

5 is a conceptual diagram schematically showing a stereoscopic projection apparatus according to another embodiment of the present invention.

5, the stereoscopic projection apparatus according to the present embodiment includes a projection unit 100, a linear polarization light modulator 200, a screen 300, and linearly polarized glasses 400. Particularly, the stereoscopic projection apparatus shown in Fig. 3 differs from the stereoscopic projection apparatus shown in Fig. 3 in the configuration of the linear polarization light modulating apparatus 200.

4, the linear polarization light modulator 200 of the stereoscopic projection apparatus according to the present embodiment further includes a back-scattering film 220. The back-

The reverse dispersion film 220 is disposed to pass the retarded light passing through the electro-optical shutter 210, and may have a reverse dispersion property for correcting the wavelength dispersion property of the liquid crystal cell.

Here, when the amount of phase delay in the state not applying power to the liquid crystal cell as R _cell, the size of the phase delay in the inverse dispersion film 220 may be set so that the _cell R / n. In this case, n is a natural number.

6 is a conceptual diagram schematically showing the polarization state of light for explaining the operation of the stereoscopic projection apparatus shown in Fig.

Referring to FIG. 6, the operation of the stereoscopic projection apparatus shown in FIG. 5 will be described as follows.

In the projection part (see 100 in Fig. 5), the image is projected with the light ( _I ). This light (l _I ) is emitted from the projection part and then passes through a linear polarization optical modulator (see 200 in Fig. 5).

The light _(I ℓ) is first linearly polarized by the polarizer passes through the line (see 205 in FIG. 5) of the linearly polarized light modulator in one direction.

The light of the left eye image passes through the electro-optical shutter when the electro-optical shutter (see 210 in Fig. 5) of the linearly polarized light modulating apparatus is in the first state, ELS _LI ) forms a first angle (e.g., 0 degrees) with the polarization axis of the linear polarizer.

Accordingly, the light of the left eye image becomes x-polarized light (L _LI ) after passing through the electro-optical shutter in the first state. At this time, due to the wavelength dispersion characteristics of the liquid crystal cell included in the electron optical shutter, light having a relatively short wavelength contained in the light of the left eye image becomes elliptically polarized light. Here, a light having a relatively short wavelength is referred to as a blue light (l _BLI ) for convenience's sake.

The light of the x-polarized left eye image (? _LI , of ℓ _BLI), all there is to pass through the reference linearly polarized light modulator reverse dispersion film (5 of 220), the polarization state of the common light (ℓ _LI) by the inverse dispersion film is maintained, and, blue light (ℓ _BLI) The polarization state is corrected by linearly polarized light.

The light from the _{backscattered} and x-polarized left eye image passed through the linear optical modulator (ℓ _LIIDF , l _BLIIDF are incident on both the left eye lens and the right eye lens of the linearly polarized glasses (see 400 in Fig. 5). When incident on the left eye lens, the light of the inverse and x-polarized left eye images (ℓ _LIIDF , ( _BLIIDF ) is the same direction as the polarization axis of the linearly polarized light filter (see 410L in Fig. 5) of the left eye lens, and the light (ℓ _LIIDF , ℓ _BLIIDF ) passes through the linearly polarized light filter of the left eye lens. Therefore, the left eye image is incident on the left eye of the user.

On the other hand, the light of the inverse and x-polarized left eye images (L _LIDF , ℓ _BLIIDF ) is also incident on the right eye lens, and the backward and x-polarized left eye image light (ℓ _LIIDF , ( _BLIIDF ) is the direction perpendicular to the polarization axis of the linear polarization filter (see 410R in Fig. 5) of the right eye lens, and the light of the inverse dispersion and x polarization left eye image ( _LIIDF , l _BLIIDF ) is blocked by the linear polarization filter of the right eye lens. Therefore, the left eye image is not incident on the user's right eye.

Although not shown in FIG. 5, when the back-scattered film of the linearly polarizing light modulating device (see 220 in FIG. 5) is omitted, the elliptically polarized blue light L _BLI can partially pass through the linearly polarized light filter of the right eye lens. Therefore, the blue elements in the image for the left eye are incident on the right eye of the user, causing a light leakage phenomenon.

The light in the right eye image passes through the electro-optical shutter when the electro-optical shutter (see 210 in Fig. 5) of the linear optical modulator is in the second state. The phase delay axis ELS _RI ) forms a second angle (e.g., 90 degrees) with the polarization axis of the linear polarizer.

Accordingly, the light in the right eye image becomes the y-polarized light ( _RI ) after passing through the electron optical shutter in the second state. At this time, due to the wavelength dispersion characteristics of the liquid crystal cell included in the electron optical shutter, light having a relatively short wavelength included in the light of the right eye image becomes elliptically polarized light. Here, light having a relatively short wavelength is referred to as blue light ( _BRI ) for convenience. That is, the polarization state of the blue light passing through the electron optical shutter becomes a state different from the polarization state of the red light and the green light passing through the electron optical shutter.

The light of this y-polarized right eye image (? _RI , ℓ _BRI), all there is to pass through the reference linearly polarized light 220 of the modulator reverse dispersion film (Fig. 5), the polarization state of the common light (ℓ _RI) by the inverse dispersion film is maintained, and, blue light (ℓ _BRI) of The polarization state is corrected by linearly polarized light. That is, the inversely dispersed film passes the red light and the green light while maintaining the polarized state as the linearly polarized light, and passes the elliptically polarized blue light so as to become the linearly polarized light, that is, the polarized state of the green light.

The light from the _{backscattered} and y-polarized right eye images (ℓ _RIIDF , ℓ _BRIIDF ) enters both the left eye lens and the right eye lens of the linearly polarized glasses (see 400 in FIG. 5). When incident on the right eye lens, the light of the inversely dispersed and y-polarized right eye images (ℓ _RIIDF , l _BRIIDF ) is the same direction as the polarization axis of the linear polarization filter (see 410R in Fig. 5) of the right eye lens, and the light of the inversely dispersed and y-polarized right eye image ( _RIIDF , ℓ _BRIIDF ) passes through the linear polarization filter of the right eye lens. Therefore, the right eye image is incident on the right eye of the user.

On the other hand, the light of the inversely dispersed and y-polarized right eye images (ℓ _RIIDF , ℓ _BRIIDF ) is also incident on the left eye lens, the light of the reverse and y-polarized right eye images (ℓ _RIIDF , linear polarization direction of the _BRIIDF ℓ) is the polarization axis normal to the direction of linear polarization of the reference filter of the left-eye lens (Fig. 5 410L), reverse dispersion and y-polarized light for the right eye image (ℓ _RIIDF, l _BRIIDF ) is blocked by the linear polarization filter of the left eye lens. Therefore, the right eye image is not incident on the left eye of the user.

Although not shown in FIG. 5, when the back-scattered film (see 220 in FIG. 5) of the linearly polarizing light modulator is omitted, the elliptically polarized blue light L _BRI can partially pass through the linearly polarized light filter of the left eye lens. Therefore, the blue elements of the right eye image are incident on the left eye of the user, causing a light leakage phenomenon.

With this principle, the light of the left eye image of the image emitted from the projection unit is incident only on the left eye of the user, and the light of the right eye image is incident on only the right eye of the user. Since the user's left eye sees only the left eye image and the right eye sees only the right eye image, the user feels the stereoscopic image according to the difference between the left eye image and the right eye image.

7 is a conceptual diagram schematically showing a stereoscopic projection apparatus according to another embodiment of the present invention.

7, the stereoscopic projection apparatus according to the present embodiment includes a projection unit 100, a linear polarization light modulator 200, a screen 300, and linearly polarized glasses 400. Particularly, the stereoscopic projection apparatus shown in Fig. 3 is different from the stereoscopic projection apparatus shown in Fig.

4, the linear polarized glasses 400 of the stereoscopic projection apparatus according to the present embodiment further include reverse dispersion films 420L and 420R.

The linearly polarized glasses 400 have a left eye lens and a right eye lens. The reverse dispersion film 420L of the left eye lens is arranged so that the image projected from the stereoscopic projection apparatus passes first before passing through the linear polarizer 410L and the reverse dispersion film 420R of the right eye lens is arranged so that the image projected from the stereoscopic projection apparatus Is passed first before passing through the linear polarizing plate 410R. The reverse dispersion films 420L and 420R disposed on the left eye lens and the right eye lens may have a reverse dispersion property for correcting the wavelength dispersion property of the liquid crystal cell.

Here, when the magnitude of the phase delay in the liquid crystal cell in a state in which no power is applied is R _cell , the size of the phase delay in the reverse dispersion films 420L and 420R may be set to be R _cell / n. In this case, n is a natural number.

8 is a view schematically showing wavelength dispersion according to another embodiment of the present invention.

Referring to FIG. 8, the wavelength dispersion according to the present embodiment is calculated as a ratio of the phase delay distance when a light having a wavelength of 550 nm is transmitted through a specific material, and a phase delay distance when light having a different wavelength is transmitted . Here, it is a matter of course that the wavelength dispersion can be calculated on the basis of a wavelength length of any visible light other than 550 nm.

In the case of a liquid crystal cell, the wavelength dispersion of the light having a wavelength exceeding 550 nm is close to 1, but the wavelength dispersion value of the light having a wavelength less than 550 nm is decreased as the wavelength is shortened. That is, when blue light having a wavelength of about 475 nm is transmitted through the liquid crystal cell, the phase delay distance becomes shorter than that when green light having a wavelength of about 510 nm or red light having a wavelength of about 650 nm is transmitted.

Due to the wavelength dispersion characteristics of the liquid crystal cell, the phase retardation distance of blue light is greatly different from that of green light and red light, and the polarization state of blue light is also greatly different from that of green light and red light. For example, when the green light and the red light pass through the linear polarizer (see 205 in FIG. 5) and the electron optical shutter 210 and have a polarized form close to linearly polarized light, the blue light may have a polarized form close to circularly polarized light. The linearly polarized green and red light

The circularly polarized blue light passes through both of the left and right eye lenses so that the projected stereoscopic image is entirely blue light. And the light leakage phenomenon which is visible is generated.

In the case of the reverse dispersion film according to the present embodiment, the light having a wavelength exceeding 550 nm has a wavelength dispersion close to 1, but the light having a wavelength less than 550 nm is set to have a higher wavelength dispersion value . That is, when blue light having a wavelength of about 475 nm is transmitted through the liquid crystal cell, the phase delay distance may be set to be longer than that when green light having a wavelength of about 510 nm or red light having a wavelength of about 650 nm is transmitted have.

Here, when the magnitude of the phase delay in the liquid crystal cell in a state in which the power source is not applied is R _cell , when the size of the phase delay in the reverse dispersion film is set to be R _cell / n, The wavelength dispersion is corrected to be close to 1, and the light leakage of the blue light can be prevented.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

110: projection unit 200: linear polarization optical modulator
205: linear polarizer 210: electron optical shutter
220: reverse dispersion film 300: screen
400: Linear polarized glasses 410L, 410R: Line polarizer
420L, 420R: reverse dispersion film

Claims (9)

A consular department capable of projecting images;
A linear polarizer having a polarization axis in one direction arranged to allow light emitted from the projection unit to pass therethrough;
A first state having a phase retardation axis disposed so as to allow light passing through the linear polarizer to pass therethrough and having a first angle with a linear polarization direction of light passing through the linear polarizer, and a second state having a second angle with the linear polarization direction of light passing through the linear polarizer An electron optical shutter for alternately switching a second state having a phase delay axis to be formed; And
And a reverse dispersion film disposed so that light passing through the electron optical shutter passes therethrough,
The polarization state of the blue light passing through the electron optical shutter becomes a state different from the polarization state of the red light and the green light having passed through the electron optical shutter,
Wherein the inversely dispersing film passes the red light and the green light while maintaining the polarized state and the blue light is changed so as to become the same polarized state as that of the green light. delete delete delete A consular department capable of projecting images;
A linear polarizer having a polarization axis in one direction arranged to allow light emitted from the projection unit to pass therethrough;
A first state having a phase retardation axis disposed so as to allow light passing through the linear polarizer to pass therethrough and having a first angle with a linear polarization direction of light passing through the linear polarizer, and a second state having a second angle with the linear polarization direction of light passing through the linear polarizer An electron optical shutter for alternately switching a second state having a phase delay axis to be formed; And
And stereoscopic glasses for wearing by the user,
Wherein either one of the left eye lens and the right eye lens of the stereoscopic spectacles use glasses has a linear polarizer having a polarization axis in the same direction as the elliptical polarization long axis direction of the light having passed through the electro-
Wherein one of the left eye lens and the right eye lens of the stereoscopic spectacles use glasses has a linear polarizer having a polarization axis in the same direction as the elliptical polarization long axis direction of light passing through the electro-
Wherein each of the left eye lens and the right eye lens of the stereoscopic spectacles use glasses has a reverse dispersion film arranged so as to pass light before entering the linear polarizer of the stereoscopic glasses,
The polarization state of the blue light passing through the electron optical shutter becomes a state different from the polarization state of the red light and the green light having passed through the electron optical shutter,
Wherein the inversely dispersing film passes the red light and the green light while maintaining the polarized state and the blue light is changed so as to become the same polarized state as that of the green light. delete delete delete A linear polarizer having a polarization axis in one direction;
A first state having a phase retardation axis disposed so as to allow light passing through the linear polarizer to pass therethrough and having a first angle with a linear polarization direction of light passing through the linear polarizer, and a second state having a second angle with the linear polarization direction of light passing through the linear polarizer An electron optical shutter for alternately switching a second state having a phase delay axis to be formed; And
And a reverse dispersion film disposed so that light passing through the electron optical shutter passes therethrough,
The polarization state of the blue light passing through the electron optical shutter becomes a state different from the polarization state of the red light and the green light having passed through the electron optical shutter,
Wherein the back-scattered film passes the red light and the green light while maintaining the polarized state, and the blue light is changed so as to become the same polarized state as the green light.

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