KR101114620B1 - A three-dimensional display system - Google Patents

Abstract

The present invention relates to a three-dimensional display system, comprising a first substrate, a second substrate spaced apart from the first substrate, a first polarizing plate positioned outside the first substrate, and an inside of the first substrate. A first electrode positioned, a first alignment layer positioned on an inner side of the first electrode, a second polarizing plate positioned outside the second substrate, a second electrode positioned inside the second substrate, A second phase film positioned inside the second electrode, a liquid crystal layer positioned between the first alignment film and the second alignment film, and a first phase positioned outside the second polarizing plate to convert linearly polarized light into circularly polarized light; A liquid crystal display including a retardation film; A first glasses substrate, a second glasses substrate disposed to be spaced apart from the first glasses substrate, a first glasses polarizing plate positioned outside the first glasses substrate, and a first glasses positioned inside the first glasses substrate An electrode, a first glasses alignment film positioned on an inner surface of the first glasses electrode, a second glasses polarizing plate located outside of the second glasses substrate, and a second glasses electrode located inside of the second glasses substrate And a second glasses alignment film positioned inside the second glasses electrode, a glasses liquid crystal layer positioned between the first glasses alignment film and the second glasses alignment film, and circularly polarized light positioned outside the first glasses polarizing plate. It provides a three-dimensional display system comprising a; shutter eyeglasses portion including a first glasses phase delay film for converting the light into linear polarization.

Description

3D display system {A THREE-DIMENSIONAL DISPLAY SYSTEM}

The present invention relates to a three-dimensional display system, and more particularly, to a three-dimensional display system that improves the structure of the three-dimensional shutter glasses and the display, and displays the three-dimensional image satisfactorily regardless of the change in the posture of the viewer.

Three-dimensional stereoscopic imaging technology generally uses the binocular parallax, which is the biggest factor in recognizing three-dimensional effect at a short distance, to make the object feel three-dimensional.

As such a three-dimensional stereoscopic imaging technique, there are a method of using glasses and a glasses-free method, and a method of using glasses includes a polarization method using polarization glasses having different polarization directions and a time-divided screen periodically, And a liquid crystal shutter eyeglass method using glasses provided with synchronized liquid crystal shutters.

1 is a view showing a stereoscopic image display device and a liquid crystal shutter glasses for implementing the liquid crystal shutter glasses method.

Referring to FIG. 1, a stereoscopic image display apparatus of a liquid crystal shutter eyeglass system alternately displays a left eye image and a right eye image alternately, and synchronizes the liquid crystal shutter eyeglasses 120 with a predetermined time to implement a stereoscopic image. That is, when the left eye image is displayed on the screen, the stereoscopic image display apparatus 110 of the liquid crystal shutter glasses type opens the left eye shutter of the liquid crystal shutter glasses, and when the right eye image is displayed, the right eye shutter of the liquid crystal shutter glasses is opened. Alternates quickly.

The conventional liquid crystal shutter glasses are all fixed by a plate, and the polarization axis of the glasses worn in the human sitting position is the same as the polarization axis of the light emitted from the liquid crystal display. In the liquid crystal shutter glasses type stereoscopic image display device having such a structure, when the user wants to watch while lying down, the light is removed by the polarizer because the polarization axis of the glasses is 90 degrees to the polarization axis of the light emitted from the liquid crystal display. Has a problem that the screen is not displayed to the user when changing the posture.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems, and an object of the present invention is to provide a three-dimensional display system that stably provides a three-dimensional image regardless of a change in a viewer's posture.

In order to achieve the above object, the present invention provides a first substrate 160, a second substrate 180 spaced apart from the first substrate, and a first polarizing plate 162 positioned outside the first substrate. ), A first electrode 164 positioned inside the first substrate 160, a first alignment layer 166 positioned on an inner side surface of the first electrode 164, and an outer side of the second substrate. A second polarizing plate 182 positioned, a second electrode 184 positioned inside the second substrate 180, a second alignment layer 186 positioned inside the second electrode 184, A first phase delay film for converting linearly polarized light into circularly polarized light, which is disposed between the liquid crystal layer 190 positioned between the first alignment layer 166 and the second alignment layer 186 and the second polarizing plate 182. A liquid crystal display unit 150 including a 195; The first eyeglass substrate 110, the second eyeglass substrate 130 spaced apart from the first eyeglass substrate 110, and the first eyeglass polarizing plate 112 positioned outside the first eyeglass substrate 110. ), A first glasses electrode 114 positioned inside the first glasses substrate 110, a first glasses alignment layer 116 positioned on an inner side surface of the first glasses electrode 114, and the second glasses 116. The second glasses polarizing plate 132 positioned outside the spectacle substrate 130, the second glasses electrode 134 positioned inside the second glasses substrate 130, and the second glasses electrode 134. The second glasses alignment layer 136 positioned inside, the glasses liquid crystal layer 140 positioned between the first glasses alignment layer 116 and the second glasses alignment layer 136, and the first glasses polarizing plate 112. A shutter eyeglass unit including a first glasses phase retardation film 145 positioned at an outer side of the circular polarized light and circularly polarized light; It includes.

Preferably, the first glasses phase delay film 145 and the first phase delay film 195 are lambda / 4 phase delay film, the optical axis of the first polarizing plate 162 and the second polarizing plate 182 is It has an angle difference of 90 degrees, the optical axis of the first glasses polarizing plate and the second glasses polarizing plate has an angle difference of 90 degrees, the optical axis of the first glasses phase delay film 145 and the second glasses polarizing plate 132 The first phase delay film 195 has an angle difference of 45 degrees with the first polarizing plate 162.

The second glasses polarizing plate 132 has an optical axis of 90 degrees, the first glasses polarizing plate 112 has an optical axis of 0 degrees, and the first glasses phase delay film 145 has an optical axis of 135 degrees or 45 degrees. The second polarizing plate 182 has an optical axis of 0 degrees, the first polarizing plate 162 has an optical axis of 90 degrees, and the first phase delay film 195 has 45 degrees or 135 degrees.

More preferably, [lambda] / 2 glasses phase delay film 246 formed between the first glasses phase delay film and the first glasses polarizing plate, and [lambda] formed between the first phase delay film and the first polarizing plate. And a two-phase retardation film 296, wherein the optical axes of the first glasses polarizing plate 212 and the second glasses polarizing plate 232 have an angle difference of 90 degrees, and the first polarizing plate 262 and the first film The optical axis of the second polarizing plate 282 has an angle difference of 90 degrees, the optical axis of the first glasses phase delay film 245 has an angle difference of 75 degrees with the optical axis of the second glasses polarizing plate 232, and the first phase The optical axis of the retardation film 295 has an angle difference of 75 degrees with the second polarizing plate 282, and the optical axis of the λ / 2 glasses phase delay film 246 has an angle difference of 15 degrees with the second glasses polarizing plate 232. In addition, the optical axis of the λ / 2 phase delay film 296 has an angle difference of 15 degrees with the second polarizing plate 282. More specifically, the second glasses polarizing plate 232 has an optical axis of 0 degrees, the first glasses polarizing plate 212 has an optical axis of 90 degrees, and the first glasses phase delay film 245 has an optical axis of 75 degrees. Or -75 degrees, the λ / 2 glasses phase delay film 246 has an optical axis of 15 degrees or -15 degrees, the second polarizing plate 282 has an optical axis of 0 degrees, the first polarizing plate 262 is The optical axis is 90 degrees, the first phase delay film 295 is 75 degrees or -75 degrees, the lambda / 2 phase delay film 296 has an optical axis of 15 degrees or -15 degrees.

On the other hand, according to the present invention, the first substrate 360, the second substrate 380 disposed to be spaced apart from the first substrate, the first polarizing plate 362 located outside the first substrate, the first substrate The first electrode 364 positioned inside the first substrate 360, the first alignment layer 366 positioned on the inner side surface of the first electrode 364, and the second substrate positioned outside the second substrate 364. The polarizing plate 382, the second electrode 384 positioned inside the second substrate 380, the second alignment layer 386 positioned inside the second electrode 384, and the first alignment layer A liquid crystal layer 390 positioned between the 366 and the second alignment layer 386, a first phase delay film 395 positioned outside the second polarizing plate 382 and converting linearly polarized light into circularly polarized light; A liquid crystal display (350) including a phase delay layer (397) positioned outside the first phase delay film and partially open and the remaining portion having a three-dimensional phase delay film (397a) formed thereon; The right polarizing plate 310 located in the user's right eye, the left polarizing plate 320 positioned at one side of the right polarizing plate and having an optical axis 90 degrees different from the right polarizing plate 310, the right polarizing plate 310 and Polarizing glasses 300 including the glasses phase retardation film 330 located on the outside of the left polarizing plate 320; It includes.

Preferably, the first phase delay film 395 has an angle difference of 45 degrees with the first polarizing plate 362, and the optical axis of the glasses phase delay film 345 is one of the left and right polarizing plates and 45 Has an angle difference of degrees.

In this case, the optical axes of the first polarizing plate 362 and the right glasses polarizing plate 320 is 0 degrees, the optical axes of the second polarizing plate 382 and the left glasses polarizing plate 320 is 90 degrees, the glasses phase delay film ( The optical axis of 330 is 135 degrees or 45 degrees, the optical axis of the first phase delay film 345 is 45 degrees or 135 degrees, and the glasses phase delay film 330 and the first phase delay film 345 are λ / 4 phase delay film.

Preferably, the lambda / 2 glasses phase delay film 446 formed between the phase delay film and the left and right polarizing plates, and the lambda / 2 phase delay formed between the first phase delay film and the first polarizing plate. And a film 496, wherein the first phase delay film 495 has an angle difference of 75 degrees with the first polarizing plate 462, and the λ / 2 phase delay film 496 has the first polarizing plate 462. ) And an angle difference of 15 degrees. More specifically, the optical axes of the first polarizing plate 462 and the left glasses polarizing plate 410 is 90 degrees, the optical axis of the second polarizing plate 482 and the right glasses polarizing plate 420 is 0 degrees, the glasses phase delay The film 330 and the first phase delay film 495 are λ / 4 phase delay films having an optical axis of 75 degrees or −75 degrees, and the λ / 2 glasses phase delay films 446 and λ / 2 phase delay films ( The optical axis of 496) is 15 degrees or -15 degrees, respectively.

According to the three-dimensional display system of the present invention described above, it has the advantage of providing a stable three-dimensional stereoscopic image to the user regardless of changes in the user's posture.

1 is a configuration diagram of a conventional three-dimensional display system.
2 is a configuration diagram of a three-dimensional display system according to a first embodiment of the present invention.
3 is a configuration diagram of a three-dimensional display system according to a second embodiment of the present invention.
4 is a configuration diagram of a three-dimensional display system according to a third embodiment of the present invention.
5 is a configuration diagram of a three-dimensional display system according to a fourth embodiment of the present invention.

Hereinafter, a 3D display system according to an exemplary embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a configuration diagram of a three-dimensional display system according to a first embodiment of the present invention.

The terms or words used in this specification and claims are not to be construed as limiting in their usual or dictionary meanings, and the inventors may appropriately define the concept of terms in order to best explain their invention in the best way possible. It should be interpreted as meaning and concept corresponding to the technical idea of the present invention based on the principle that the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It should be understood that various equivalents and modifications may be present.

Referring to FIG. 2, the 3D display system according to an exemplary embodiment of the present invention includes a liquid crystal display unit 150 and a shutter eyeglass unit 100.

The liquid crystal display unit 150 includes first and second substrates 160 and 180, first and second polarizing plates 162 and 182 positioned on one side of the first and second substrates, and the first and second substrates. First and second electrodes 164 and 184 on the other side of the 160 and 180, and first and second alignment layers 166 on the inner side of the first and second electrodes 164 and 184. 186 and the liquid crystal layer 190 and the first phase delay film 195.

The first substrate 160 is disposed spaced apart from the second substrate 180 by a predetermined interval, and the first and second substrates 160 and 180 are made of glass.

The first polarizing plate 162 is disposed outside of the first substrate (upper side in FIG. 2). The first polarizing plate 162 is formed of a polarizing plate having an optical axis of 90 degrees.

The first electrode 164 is formed inside the first substrate. The first electrode 164 may be made of a transparent conductive material such as indium tin oxide (ITO) or indium zinc oxide (IZO).

The first alignment layer 166 is formed inside the first electrode. The first alignment layer 166 has a function of orienting liquid crystal molecules.

On the other hand, the second polarizing plate 182 is disposed outside the second substrate 180, the second polarizing plate 182 is formed to have an angle difference of 90 degrees with the optical axis of the first polarizing plate 162. The optical axis of the second polarizing plate of this embodiment is formed at 0 degrees.

A second electrode is formed inside the second substrate. The second electrode may also be made of a transparent conductive material such as indium tin oxide (ITO) or indium zinc oxide (IZO).

A second alignment layer is positioned inside the second electrode, and the liquid crystal layer is formed between the second alignment layer and the first alignment layer. The first and second alignment layers have a function of orienting liquid crystal molecules of the liquid crystal layer.

A first phase delay film for converting linearly polarized light that has passed through the liquid crystal into circularly polarized light is formed outside the second polarizing plate. The first phase delay film is made of λ / 4 phase delay film, and the optical axis of the first phase delay film 195 has an angle difference of 45 degrees with the optical axis of the first polarizing plate 162. The optical axis of the first phase delay film in this embodiment is 45 degrees or 135 degrees.

The shutter eyeglass unit 100 includes first and second glasses substrates 110 and 130, first and second glasses polarizing plates 112 and 132, and first and second glasses electrodes 114 and 134. And the first and second glasses alignment layers 116 and 136, the glasses liquid crystal layer 140, and the first glasses phase delay film 145.

The first and second glasses substrates 110 and 130 are spaced apart from each other, and a first glasses polarizing plate is positioned outside the first glasses substrate. The optical axis of the first glasses polarizing plate 112 has an angle difference of 90 degrees with the second glasses polarizing plate. The optical axis of the first glasses polarizing plate 112 of this embodiment is 0 degrees.

The first glasses electrode 114 is positioned inside the first glasses substrate 110, and the first glasses alignment layer 116 is positioned on the inner surface of the first glasses electrode 114.

On the other hand, the second glasses polarizing plate 136 is located outside the second glasses substrate. The optical axis of the second glasses polarizing plate 132 has an angle difference of 90 degrees with the first glasses polarizing plate. The optical axis of the second glasses polarizing plate of this embodiment is 90 degrees.

In addition, a second glasses electrode and a second glasses alignment layer are sequentially formed inside the second glasses substrate 130. The spectacle liquid crystal layer is formed between the first and second glasses alignment layers.

The second glasses alignment film has a function of orienting liquid crystal molecules of the spectacle liquid crystal layer.

A first glasses phase delay film for converting circularly polarized light supplied from the liquid crystal display into linearly polarized light is formed outside the first glasses polarizing plate.

The first glasses phase delay film is made of λ / 4 phase delay film, and the optical axis of the first glasses phase delay film 145 is formed to have an angle difference of 45 degrees with the second glasses polarizing plate 132. . The optical axis of the first glasses phase delay film of the present embodiment is formed at 45 degrees or 135 degrees when the optical axis of the second glasses polarizing plate is 90 degrees.

Meanwhile, a driving unit (not shown) for supplying power to the first and second electrodes and the first and second glasses electrodes is provided. The driving unit supplies a predetermined voltage to the first and second eyeglass electrodes to alternately operate the left eye shutter and the right eye shutter of the shutter eyeglass part, and simultaneously supplies a predetermined power to the first and second electrode to provide the left eye image and the right eye image. To be displayed.

Hereinafter, the three-dimensional display system according to the first embodiment of the present invention configured as described above operates as follows.

When the driver supplies a voltage to the first and second electrodes, the liquid crystal display arranges the liquid crystal layer to alternately display a left eye image and a right eye image. The light passing through the liquid crystal layer passes through the second polarizing plate, and only light linearly polarized in the direction of the polarization axis of the second polarizing plate remains.

The linearly polarized light passing through the second polarizing plate passes through the first phase retardation film λ / 4 phase delay film and is converted into circularly polarized light.

The circularly polarized light is irradiated to the shutter glasses unit 100 and passes through the first glasses phase delay film 145 and is converted into linearly polarized light.

At the same time, the driving unit applies a predetermined voltage to the first and second eyeglass electrodes to alternately operate the left and right shutters of the shutter eyeglasses according to the left eye image and the right eye image so that the user can recognize a stereoscopic image.

In the three-dimensional display system according to the first exemplary embodiment of the present invention, since circularly polarized light is incident on the shutter eyeglass part, the first and second glasses polarizing plates pass through the first eyeglass phase delay film regardless of the rotation direction of the shutter eyeglass part. It becomes linearly polarized light that penetrates and light of maximum intensity is incident on the liquid crystal.

Accordingly, the user can enjoy a stable three-dimensional image regardless of posture.

3 is a configuration diagram of a three-dimensional display system according to a second embodiment of the present invention.

Referring to FIG. 3, in the three-dimensional display system according to the second embodiment of the present invention, λ is between the first glasses phase delay film 245 and the first glasses polarizing plate 212 of the first embodiment of the present invention. A / 2 glasses phase delay film 246 is further formed, and a lambda / 2 phase delay film 296 is further formed between the first phase delay film 295 and the first polarizing plate 282.

In the three-dimensional display system according to the second embodiment of the present invention, a? / 2 phase delay film 296 is formed between the first phase delay film and the first polarizing plate to convert all wavelengths into circularly polarized light.

Further, a lambda / 2 glasses phase delay film 246 is further formed between the first glasses phase delay film 245 and the first glasses polarizing plate to convert the light of all circularly polarized wavelengths into linearly polarized light again. do.

In this case, an optical axis of the first glasses polarizing plate 212 and the second glasses polarizing plate 232 has an angle difference of 90 degrees, and an optical axis of the first polarizing plate 262 and the second polarizing plate 282 is 90 degrees. The optical axis of the first glasses phase delay film 245 has an angle difference of 75 degrees with the optical axis of the second glasses polarizing plate 232, the optical axis of the first phase delay film 295 is the first The polarizing plate 282 has an angle difference of 75 degrees. In the present exemplary embodiment, the optical axes of the second glasses polarizing plate 232 and the second polarizing plate 282 are equal to 0 degrees, and the optical axes of the first glasses polarizing plate 212 and the first polarizing plate 262 are 90 degrees. It is also.

The optical axis of the first glasses phase delay film 245 and the first phase delay film 295 is 75 degrees or -75 degrees with an angle difference of 75 degrees with the second glasses polarizing plate 232, and the λ / The optical axes of the binocular phase delay film 246 and the λ / 2 phase delay film 296 are formed at 15 degrees or -15 degrees having an angle difference of 15 degrees with the second glasses polarizing plate 232.

4 is a configuration diagram of a three-dimensional display system according to a third embodiment of the present invention.

Referring to FIG. 4, the three-dimensional display system according to the third exemplary embodiment of the present invention includes a liquid crystal display 350 and a polarizing glasses 300.

In the three-dimensional display system according to the third embodiment of the present invention, the shutter eyeglass part of the first embodiment is changed to a polarizing eyeglass part, and a phase delay layer is formed on the liquid crystal display part. Is the same as

Therefore, the description of the same configuration as in the first embodiment will be omitted, and the description will be mainly given on the difference configuration.

The polarizing glasses part 300 includes a right polarizing plate 310, a left polarizing plate 320, and a glasses phase delay film 330.

The right polarizing plate is a polarizing plate positioned to correspond to the user's right eye, and the left polarizing plate is located on one side of the right polarizing plate and formed to correspond to the left eye of the user. The left and right polarizers are formed such that optical axes are 90 degrees apart from each other. The left polarizing plate 320 of this embodiment has an optical axis of 90 degrees, and the right polarizing plate 310 has an optical axis of 0 degrees.

On the outside of the left and right polarizing plate, the glasses phase delay film 330 is formed. The glasses phase delay film 330 is a λ / 4 phase delay film, and the optical axis of the glasses phase delay film 330 has an angle difference of 45 degrees with the left polarizing plate. The glasses phase delay film 330 of this embodiment has an optical axis of 135 degrees or 45 degrees.

On the other hand, the phase delay layer 397 is formed outside the first phase delay film 395 of the liquid crystal display. An opening portion 397b is formed at a portion of the phase delay layer, and a three-dimensional phase delay layer 397a is formed at the remaining portion. The 3D phase delay film is a λ / 2 phase delay film generally used in a general 3D polarization system, and a detailed description thereof will be omitted.

The optical axis of the first polarizing plate 362 according to the third embodiment of the present invention and the optical axis of the right polarizing plate are 0 degrees, and the optical axis of the second polarizing plate 382 and the optical axis of the left polarizing plate are 90 degrees. The optical axis of the first phase delay film 395 is formed at 45 degrees or 135 degrees having an angle difference of 45 degrees with the first polarizing plate, and the optical axis of the spectacle phase delay film 330 is formed at 135 degrees or 45 degrees.

The three-dimensional display system according to the third exemplary embodiment of the present invention configured as described above includes a first phase delay film 395 on the liquid crystal display and a lambda / 2 phase delay film 397a on the first phase delay film. When the phase delay layer 397 in which the open portion 397b without phase delay is formed periodically is formed, left circularly polarized light is generated at one part and right circularly polarized light is generated at another part. When the light passes through the glasses phase delay film 330 of the polarizing glasses, the left circularly polarized light and the right circularly polarized light are respectively converted into linearly polarized states having an optical axis of 90 degrees. In this embodiment, the left circularly polarized light is in a 90 degree linearly polarized state, and the right circularly polarized light is in a 0 degree linearly polarized state.

In this case, the user sees the right circular polarization information with the right eye through the right eye polarizer with the optical axis of 0 degrees, and the left circular polarization information with the left eye through the left eyeglass polarizer with the optical axis of 90 degrees. You can see it.

5 is a configuration diagram of a three-dimensional display system according to a fourth embodiment of the present invention.

Referring to FIG. 5, a three-dimensional display system according to a fourth embodiment of the present invention includes a space between the glasses phase delay film 430 and the left and right polarizing plates 410 and 420 of the third embodiment of the present invention. A three-dimensional display in which a lambda / 2 phase retardation film 446 is further formed, and a lambda / 2 phase delay film 496 is further formed between the first phase delay film 495 and the first polarizing plate 482. System.

In the three-dimensional display system according to the fourth embodiment of the present invention, a? / 2 phase delay film 496 is formed between the first phase delay film and the first polarizing plate to convert all wavelengths into circularly polarized light.

Further, a λ / 2 glasses phase delay film 446 is further formed between the left and right polarizing plates and the first glasses polarizing plate to convert the light of all circularly polarized wavelengths into linearly polarized light again.

In this case, the optical axes of the first polarizing plate 462 and the left eyeglass polarizing plate 410 are 90 degrees, and the optical axis of the second polarizing plate 482 and the right eyeglass polarizing plate 420 is 0 degrees.

The optical axis of the first phase delay film 495 has an angle difference of 75 degrees with the first polarizing plate 462, and the optical axis of the eyeglass phase delay film 430 has an angle difference of 75 degrees with the right polarizing plate 410. Are formed to have 75 degrees or -75 degrees, respectively.

The λ / 2 phase delay film 446 has an angle difference of 15 degrees with the right polarizing plate, and the λ / 2 phase delay film 496 has an angle difference of 15 degrees with the first polarizing plate 462, respectively. It is formed at 15 degrees or -15 degrees.

As mentioned above, although this invention was demonstrated by the limited embodiment and drawing, this invention is not limited by this, The person of ordinary skill in the art to which this invention belongs, Of course, various modifications and variations are possible within the scope of equivalent claims.

100: shutter eyeglasses 110: the first glasses substrate
112: first glasses polarizing plate 132: second glasses polarizing plate
114: first glasses electrode 134: second glasses electrode
145: first glasses phase delay film 150: liquid crystal display
195: 1st phase delay film

Claims (14)

The first substrate 160, the second substrate 180 spaced apart from the first substrate, the first polarizing plate 162 positioned outside the first substrate, and the inside of the first substrate 160. The first electrode 164 located at the first side, the first alignment layer 166 at the inner side surface of the first electrode 164, the second polarizing plate 182 positioned at the outside of the second substrate, The second electrode 184 located inside the second substrate 180, the second alignment film 186 located inside the second electrode 184, the first alignment film 166, and the second second electrode 184. The liquid crystal display unit 150 including a liquid crystal layer 190 positioned between the alignment layers 186 and a first phase delay film 195 positioned outside the second polarizing plate 182 to convert linearly polarized light into circularly polarized light. Wow;
The first eyeglass substrate 110, the second eyeglass substrate 130 spaced apart from the first eyeglass substrate 110, and the first eyeglass polarizing plate 112 positioned outside the first eyeglass substrate 110. ), A first glasses electrode 114 positioned inside the first glasses substrate 110, a first glasses alignment layer 116 positioned on an inner side surface of the first glasses electrode 114, and the second glasses 116. The second glasses polarizing plate 132 positioned outside the spectacle substrate 130, the second glasses electrode 134 positioned inside the second glasses substrate 130, and the second glasses electrode 134. The second glasses alignment layer 136 positioned inside, the glasses liquid crystal layer 140 positioned between the first glasses alignment layer 116 and the second glasses alignment layer 136, and the first glasses polarizing plate 112. A shutter eyeglass unit including a first glasses phase retardation film 145 positioned at an outer side of the circular polarized light and circularly polarized light; Including,
The first glasses phase delay film 145 and the first phase delay film 195 are lambda / 4 phase delay film,
The optical axis of the first polarizing plate 162 and the second polarizing plate 182 has an angle difference of 90 degrees, the optical axis of the first glasses polarizing plate and the second glasses polarizing plate also has an angle difference of 90 degrees, and the first The optical axis of the glasses phase delay film 145 has an angle difference of 45 degrees with the second glasses polarizing plate 132, and the first phase delay film 195 has an angle difference of 45 degrees with the first polarizing plate 162. 3D display system.
delete delete The method according to claim 1,
The second glasses polarizing plate 132 has an optical axis of 90 degrees, the first glasses polarizing plate 112 has an optical axis of 0 degrees, and the first glasses phase delay film 145 has an optical axis of 135 degrees or 45 degrees,
The second polarizing plate (182) has an optical axis of 0 degrees, the first polarizing plate (162) has an optical axis of 90 degrees, and the first phase delay film (195) is 45 degrees or 135 degrees.
The method according to claim 1,
[Lambda] / 2 glasses phase delay film 246 formed between the first glasses phase delay film and the first glasses polarizing plate, and [lambda] / 2 phase delay film formed between the first phase delay film and the first polarizing plate. 3D display system further comprising (296).
The method according to claim 5,
The optical axis of the first glasses polarizing plate 212 and the second glasses polarizing plate 232 has an angle difference of 90 degrees,
The optical axis of the first polarizing plate 262 and the second polarizing plate 282 has an angle difference of 90 degrees,
The optical axis of the first glasses phase delay film 245 has an angle difference of 75 degrees with the optical axis of the second glasses polarizing plate 232,
The optical axis of the first phase delay film 295 has an angle difference of 75 degrees with the second polarizing plate 282,
The optical axis of the λ / 2 glasses phase delay film 246 has an angle difference of 15 degrees with the second glasses polarizing plate 232,
And the optical axis of the [lambda] / 2 phase delay film (296) has an angle difference of 15 degrees with the second polarizing plate (282).
The method of claim 6,
The second glasses polarizing plate 232 has an optical axis of 0 degrees, the first glasses polarizing plate 212 has an optical axis of 90 degrees, and the first glasses phase delay film 245 has an optical axis of 75 degrees or -75 degrees. The λ / 2 glasses phase delay film 246 has an optical axis of 15 degrees or -15 degrees,
The second polarizing plate 282 has an optical axis of 0 degrees, the first polarizing plate 262 has an optical axis of 90 degrees, and the first phase delay film 295 is 75 degrees or -75 degrees, and the lambda / 2 The phase delay film 296 is a three-dimensional display system having an optical axis of 15 degrees or -15 degrees.
A first substrate 360, a second substrate 380 spaced apart from the first substrate, a first polarizing plate 362 positioned outside the first substrate, and an inside of the first substrate 360. A first electrode 364 positioned at the first side, a first alignment layer 366 positioned at the inner side surface of the first electrode 364, a second polarizing plate 382 positioned outside the second substrate, and The second electrode 384 positioned inside the second substrate 380, the second alignment layer 386 positioned inside the second electrode 384, the first alignment layer 366 and the second second electrode 384. A liquid crystal layer 390 positioned between the alignment layers 386, a first phase delay film 395 positioned outside the second polarizing plate 382 to convert linearly polarized light into circularly polarized light, and the first phase delay film A liquid crystal display unit 350 which includes a phase delay layer positioned at an outer side and part of which is open and a remaining portion has a three-dimensional phase delay layer 397 formed thereon;
The right polarizing plate 310 located in the user's right eye, the left polarizing plate 320 positioned at one side of the right polarizing plate and having an optical axis 90 degrees different from the right polarizing plate 310, the right polarizing plate 310 and Polarizing glasses 300 including the glasses phase retardation film 330 located on the outside of the left polarizing plate 320;
Three-dimensional display system comprising a.
The method according to claim 8,
The first phase delay film 395 has an angle difference of 45 degrees with the first polarizing plate 362, and the optical axis of the glasses phase delay film 345 has an angle difference of 45 degrees with one polarizing plate among the left and right polarizing plates. Three-dimensional display system.
The method according to claim 9,
The optical axis of the first polarizing plate 362 and the right glasses polarizing plate 320 is 0 degrees, the optical axis of the second polarizing plate 382 and the left glasses polarizing plate 320 is 90 degrees, the optical phase delay film 330 The optical axis is 135 degrees or 45 degrees, and the optical axis of the first phase delay film 345 is 45 degrees or 135 degrees.
The method according to claim 9,
The glasses phase retardation film 330 and the first phase retardation film 345 are lambda / 4 phase retardation film.
The method of claim 11,
[Lambda] / 2 glasses phase delay film 446 formed between the glasses phase delay film and the left and right polarizing plates, and [lambda] / 2 phase delay film formed between the first phase delay film and the first polarizing plate (196). 3D display system further comprising).
The method of claim 12,
The first phase delay film 495 has an angle difference of 75 degrees with the first polarizing plate 462, and the λ / 2 phase delay film 496 has an angle difference of 15 degrees with the first polarizing plate 462. Dimensional display system.
The method according to claim 13,
The optical axis of the first polarizing plate 462 and the left eyeglass polarizing plate 410 is 90 degrees, the optical axis of the second polarizing plate 482 and the right eyeglass polarizing plate 420 is 0 degrees, and the glasses phase delay film 330 and The first phase delay film 495 is a λ / 4 phase delay film having an optical axis of 75 degrees or -75 degrees, and the optical axes of the λ / 2 glasses phase delay film 446 and the λ / 2 phase delay film 496 are Three-dimensional display system that is 15 degrees or -15 degrees.

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