DE102005019839B4 - Liquid crystal projection system - Google Patents

Abstract

Liquid crystal projection system, comprising:
a light source (21) for emitting a white light;
a polarization component (22) for polarizing the white light to produce a polarized light;
a dichroic mirror (24) for receiving the polarized light and dividing the polarized light into dual primary colors and a single primary color for output;
a λ / 2 retardation plate (34) disposed at the dichroic mirror (24);
a reflection prism (25) disposed on an output side of the dichroic mirror (24) for receiving the single primary color and then reflecting the single primary color for output;
a first polarization component (26) disposed on another output side of the dichroic mirror (24) for receiving and then polarizing the dual primary colors;
a second polarization component (27) disposed on an output side of the reflection prism (25) for receiving the single primary color and then polarizing the single primary color;
a dichroic component (28) disposed on the first polarization component (26) for receiving and splitting the dichroic primary color, the reflective prism (25), the first polarization component (26), the ...

Description

The The invention relates to a liquid crystal projection system and in particular a liquid crystal projection system, to achieve equal optical paths during projection, three reflection type liquid crystal panels used.

conventional CRT ads are due to volume and cost considerations not for large ads suitable. The liquid crystal projection technology creates a compact display with a quality similar to that of the conventional CRT display is the same.

Projector Architecture is either single panel or triple panel. The single panel projector has a low resolution and low brightness, but is inexpensive. The triple-panel projector has a high resolution and high brightness, but is expensive. The currently used Projection technology is almost only of the mature transmission type. However, the transmission type projector has the problem of a small aperture ratio on.

The Taiwanese patent TW 556.041 A discloses a reflection type projection technique using three reflection type liquid crystal panels for image projection to provide a large aperture ratio and a high resolution, bright display.

1 shows the architecture of the in TW 556.041 A disclosed liquid crystal projection system. There are optical paths from a light source 11 to three reflection type liquid crystal panels 20 . 21 and 22 and optical paths from the reflection type liquid crystal panels 20 . 21 and 22 to the projection lens 23 , In the optical paths of the light source 11 to the reflection type liquid crystal panels 20 . 21 and 22 gets light from the light source 11 by means of a dichroic mirror 14 divided into two light beams, one being a polarized dual primary color light beam Rp and Bp, the other being a polarized single primary color light beam Gp. The polarized dual primary color light rays Rp and Bp are passed through a polarizing beam splitter 16 and a dichroic prism 18 to the respective reflection type liquid crystal panels 21 respectively. 22 pass through. The polarized single primary color light beam Gp is reflected by a reflection mirror 15 and a polarizing beam splitter to the reflection type liquid crystal panel 20 pass through.

In the above description, the polarized single primary color light beam Gp with air as the medium becomes the reflection mirror 15 and then through the polarizing beam splitter 17 made of a glass material to the reflection type liquid crystal panel 20 pass through. The polarized dual primary color light rays Rp and Bp are passed through the polarizing beam splitter 16 made of glass material, to the respective reflection type liquid crystal panels 21 respectively. 22 pass through. Therefore, the optical paths of the polarized double-primary-color light beams Rp and Bp and the polarized single-primary-color light beam Gp from the light source are 11 to the reflection type liquid crystal panels 20 . 21 and 22 unlike, resulting in a disturbance and reduction in the uniformity of the light source of the liquid crystal projection system during projection.

The document TW 556041 A Therefore, it can be summarized by including therein a liquid crystal projection system having a beam splitting unit dividing polarized light, first and second polarizers at the output of the beam splitter unit, a dichroic device, two modulating devices, a delay unit, and a projection lens is arranged between the two modulation devices.

From the document EP 1146383 A1 is a reflection liquid crystal projection system known, wherein two polarizing beam splitters are provided on a dichroic prism. A dichroic mirror separates light from the illumination source into two different color components and provides each component to one of the two beam splitters.

task the invention is to provide a liquid crystal projection system, in which the optical path of the polarized single primary color light beam from the light source to the reflection liquid crystal panel and the optical path of the polarized double-primary color light beams from the light source the reflection type liquid crystal panels while a projection are aligned.

To the Achieving the above object uses the liquid crystal projection system according to the invention a light source for emitting a white light. The white light source is used to generate a polarized light from a polarization component polarized. The polarized light is made by means of a dichroic Mirror in dual primary colors and a single primary color divided up.

In the dichroic mirror, a λ / 2 retardation plate is arranged. The single primary color is reflected for output by a reflection prism located on an output side of the dichroic mirror. The dual primary colors are received and polarized by a first polarization component the other output side of the dichroic mirror is arranged. A second polarization component is disposed on an output side of the reflection prism and used to polarize the single primary color. The polarized dual primary colors are sent for splitting to a dichroic component which is attached to the first polarization component (FIG. 26 ), wherein the reflection prism, the first polarization component, the second polarization component, and the dichroic component are combined to form a Z-shaped prism module. A modulation device is disposed on the second polarization component and the dichroic component and modulates the dual and single primary colors into the other polarization state and then reflects them for output. A projection lens is disposed on the first polarization component, receives the modulated double and single primary colors, and projects the output light beam onto a screen.

According to one Another aspect of the invention includes the liquid crystal projection system Light source for emitting a white light, a polarization component to polarize the white Light to produce a polarized light, a dichroic Mirror for receiving the polarized light and splitting the polarized light in dual primary colors and a single primary color to Output and arranged at the dichroic mirror λ / 2-delay plate on. Further, at an output side of the dichroic mirror is a polarizing beam splitter for receiving and polarizing the Single-primary color arranged for issue. At another exit side of the dichroic Mirror is a first polarization component for receiving and then Polarizing the dual primary colors arranged. At an output side of the polarizing beam splitter is a second polarization component for receiving the single primary color and then polarizing the single primary color arranged. Further is at the first polarization component a dichroic component arranged to receive and divide the dichroic primary color, wherein the polarizing beam splitter, the first polarization component, the second polarization component and the dichroic component to a Z-shaped Prism module are combined. At the second polarization component and the dichroic component is a modulation device for Receiving, modulating in a different polarization state and then reflecting the double primary colors and the single primary color and at the first polarization component is a projection lens for receiving the modulated double and single primary colors and projecting outward arranged on a display screen.

The Various objects and advantages of the invention will become apparent from the following detailed description better understood when combined with the attached Drawing is read, in the:

1 Fig. 10 is an architectural diagram of a conventional liquid crystal projection system;

2 Fig. 10 is an architectural diagram of a first embodiment of the invention;

3 Fig. 3 is an architectural diagram of a second embodiment of the invention;

4 Fig. 3 is an architectural diagram of a third embodiment of the invention;

5 Fig. 3 is an architectural diagram of a fourth embodiment of the invention; and

6 Fig. 3 is an architectural diagram of a fifth embodiment of the invention.

As in 2 1, a liquid crystal projection system according to a first embodiment of the invention has a light source 21 for emitting white light, a polarization component 22 to polarize the white light, a dichroic mirror 24 for splitting the light beam, a reflection prism 25 for reflecting the light beam, a first polarization component 26 and a second polarization component 27 to polarize light, a dichroic component 28 for dichroic processing, a modulation device 29 for light modulation and a projection lens 33 to the output beam projection. The polarization component 22 is for splitting unpolarized white light into polarized light (s-polarization or p-polarization) of three primary colors (R, G, B) in the optical output path of the light source 21 arranged.

In the above illustration are the dichroic mirror 24 and the reflection prism 25 for dividing the output light beam of the polarization component into two light beams in the output direction of the polarization component 22 arranged. The dichroic mirror 24 splits the output polarized light from the three primary colors of the polarization component 22 into two light rays, one being a polarized dual primary color light beam coming from the dichroic mirror 24 is outputted directly while the other is a polarized single primary color light beam emitted from the reflection prism 25 is reflected. The first polarization component 26 is at the dichroic mirror 24 and is used for passing or reflecting the polarized double-primary-color light beams according to the state of polarization (p-polarization or s-polarization) det. The second polarization component 27 is on the reflection prism 25 and is used to pass or reflect the polarized single primary color light beam according to the state of polarization (p-polarization or s-polarization).

The dichroic component 28 is at the first polarization component 26 and is used for reflecting one of the polarized dual primary color light beams and passing the other one. The modulation device modulates the input polarized light into polarized light of the other polarization state having image signals, and then reflects the same for output. The modulation device 29 has a first reflection type liquid crystal panel 30 , a second reflection type liquid crystal panel 31 and a third reflection type liquid crystal panel 32 on. The first reflection type liquid crystal panel 31 is at the second polarization component 27 arranged. The second and third reflection type liquid crystal panel 31 respectively. 32 are each on one of two sides of the dichroic component 28 arranged. The projection lens 33 is at the first polarization component 26 is arranged and is for projecting the of the modulation device 29 modulated light used for display on a display screen.

In addition, a λ / 2 retardation plate 34 at the dichroic mirror 24 arranged. The λ / 2-delay plate 34 is used to change the state of polarization (p-polarization or s-polarization) of the light beam. As in 2 shown is the light beam passing through the polarization component 22 through to the dichroic mirror 24 is transmitted, p-polarized. The λ / 2-delay plate 34 is between the dichroic mirror 24 and the reflection prism 25 and is used to change the polarization state of the light beam. If the polarization state of a light beam is s-polarization, that is, by the polarization component 22 to the dichroic mirror 24 transmitted light beam is s-polarized, is the λ / 2 retardation plate 34 (not shown) for changing the polarization state of the light beam between the dichroic mirror 24 and the first polarization component 26 arranged. A polarizing plate 36 and a wavelength-selective polarizing plate 36a are for avoiding non-uniformity or leakage of light during light transmission for improving the purity effect between the first polarization component 26 and the projection lens 33 arranged.

It will be up again 2 Referenced. The output light of the polarization component 22 is Wp. The dichroic mirror 24 Reflects the green light Gp in the polarized light of the three primary colors Wp and passes the red light Rp and the blue light Bp. The polarization state of the green light Gp is from the λ / 2 retardation plate 34 changed to a green light Gs. The green light Gs is emitted by the reflection prism 25 to the second polarization component 27 reflected. The second polarization component 27 is a polarizing beam splitter (PBS) that transmits p-polarized light and reflected polarized light. Therefore, the green light Gs becomes the second polarization component 27 to the first reflection type liquid crystal panel 30 reflected and then by means of the first reflection type liquid crystal panel 30 into a green light Gp of the other polarization state having image signals modulated. This green light Gp becomes the second polarization component 27 reflected and then to the first polarization component 26 pass through. That of the dichroic mirror 24 output red and blue light (RpBp) becomes the first polarization component 26 pass through. The first polarization component 26 is a PBS that also transmits p-polarized light and reflected polarized light. Therefore, the red and blue light (RpBp) becomes the dichroic component 28 pass through. The dichroic component 28 is a dichroic prism that reflects red light R and transmits blue light B. That is, the red light Rp becomes the second reflection type liquid crystal panel 31 while the blue light Bp is reflected to the third reflection type liquid crystal panel 32 is allowed through. The red light Rp becomes of the second reflection type liquid crystal panel 31 in a red light Rs of the other polarization state, which has image signals modulated. This red light Rs then becomes the dichroic component 28 reflected. The blue light Bp becomes of the third reflection type liquid crystal panel 32 in a blue light Bs of the other polarization state, which has image signals modulated. This blue light Bs then becomes the dichroic component 28 reflected. The dichroic component 28 gives the red and blue light (RsBs) to the first polarization component 26 out. The first polarization component 26 reflects the red and blue light RsBs, that of the dichroic component 28 to the projection lens 33 is output, and leaves the green light Gp, that of the second polarization component 27 is output to the projection lens 33 by.

The green light Gp is then emitted by the wavelength selective polarizing plate 36a transformed into a green light Gs. Subsequently prepares the polarizing plate 36 the lights of RsGsB on. Finally, that of the projection lens 33 output light beam image signals and is projected to display the image frame on a display screen.

In the above illustration, the polarized single primary color light beam is a green light Gp corresponding to the reflection prism 25 made of glass and then by the PBS 27 made of glass to the reflection type liquid crystal panel 30 is allowed through. The red and blue lights Rp and Bp are respectively through the PBS 26 made of glass and the dichroic prism 28 to the reflection type liquid crystal panels 31 respectively. 32 pass through. Therefore, the optical paths of the polarized double primary color light beams Rp and Bp and the single primary color light beam Gp from the light source are 21 to the reflection type liquid crystal panels 30 . 31 and 32 equal. The disadvantages of interference and reduction of the uniformity of the light source of the liquid crystal projection system during projection can be reduced. The above reflection prism 25 may be a triangular reflection prism.

Reference is the same way 3 taken as on 2 , The reflection prism 25 , the first polarization component 26 , the second polarization component 27 and the dichroic component 28 can in a Z-shaped prism module 20 be combined. The Z-shaped prism module 20 combines the use of the polarization component 22 , the λ / 2 retardation plate 34 , the modulation device 29 , the wavelength-selective polarizing plate 36a , the polarizing plate 36 and the projection lens 33 to detect the optical paths of the polarized double primary color light beams Rp and Bp and the single primary color light beam Gp from the light source 21 to the reflection type liquid crystal panels 30 . 31 and 32 equalize. The disadvantages of interference and reduction of the uniformity of the light source of the liquid crystal projection system during projection can be reduced. The above reflection prism 25 may be a triangular reflection prism.

Reference is just as well 4 taken as to 2 , The reflection prism used in the first embodiment 25 is in this embodiment by a PBS 23 replaced. The PBS 23 may transmit or reflect the polarized single-primary-color light beam according to the state of polarization (p-polarization or s-polarization). Therefore, the PBS replaces 23 the function of the reflection prism 25 effective at the same position. In this embodiment, the same optical paths as in the first embodiment can be achieved. The above PBS 23 may be a triangular PBS.

Reference is just as well 5 taken as to 4 , The PBS 23 , the first polarization component 26 , the second polarization component 27 and the dichroic component 28 can in a Z-shaped prism module 40 be combined. The Z-shaped prism module 40 may be the use of the polarization component 22 , the λ / 2 retardation plate 34 , the modulation device 29 , the wavelength-selective polarizing plate 36a , the polarizing plate 36 and the projection lens 33 combine the optical paths of the polarized dual primary color light beams Rp and Bp and the single primary color light beam Gp from the light source 21 to the reflection type liquid crystal panels 30 . 31 and 32 equalize. The disadvantages of interference and reduction of the uniformity of the light source of the liquid crystal projection system during projection can be reduced. The above PBS 23 can be a triangular PBS.

Reference is made to 6 , as well as 2 to 5 , In this embodiment, the reflection type liquid crystal panel is 31 originally in the first, second, third and fourth embodiments on one side of the dichroic prism 28 is arranged, arranged on the other side. However, the same optical path as in the first, second, third and fourth embodiments can be obtained.

11

Lichtquelle

14

dichroitischer Spiegel

15

Reflektionsspiegel

16

erste Polarisationskomponente

17

zweite Polarisationskomponente

18

dichroitische Komponente

20

erstes Reflektionstyp-Flüssigkristallpaneel

12

zweites Reflektionstyp-Flüssigkristallpaneel

13

drittes Reflektionstyp-Flüssigkristallpaneel

23

Projektionslinse

State of the art

11

light source

14

dichroic mirror

15

reflection mirror

16

first polarization component

17

second polarization component

18

dichroic component

20

first reflection type liquid crystal panel

12

second reflection type liquid crystal panel

13

third reflection type liquid crystal panel

23

projection lens

21

Lichtquelle

22

Polarisationskomponente

24

dichroitischer Spiegel

25

Reflektionsspiegel

26

erste Polarisationskomponente

27

zweite Polarisationskomponente

28

dichroitische Komponente

29

Modulationsvorrichtung

30

erstes Reflektionstyp-Flüssigkristallpaneel

31

zweites Reflektionstyp-Flüssigkristallpaneel

32

drittes Reflektionstyp-Flüssigkristallpaneel

33

Projektionslinse

34

λ/2-Verzögerungsplättchen

36

Polarisationsplatte

36a

Wellenlängen-selektive Polarisationsplatte

invention

21

light source

22

polarization component

24

dichroic mirror

25

reflection mirror

26

first polarization component

27

second polarization component

28

dichroic component

29

modulation device

30

first reflection type liquid crystal panel

31

second reflection type liquid crystal panel

32

third reflection type liquid crystal panel

33

projection lens

34

λ / 2 retardation plate

36

polarizing plate

36a

Wavelength-selective polarizing plate

Claims (12)

A liquid crystal projection system comprising: a light source ( 21 ) for emitting a white light; a polarization component ( 22 ) for polarizing the white light to produce a polarized light; a dichroic mirror ( 24 ) for receiving the polarized light and dividing the polarized light into dual primary colors and a single primary color for output; one in the dichroic mirror ( 24 ) arranged λ / 2-delay plate ( 34 ); one on an exit side of the dichroic mirror ( 24 ) arranged reflection prism ( 25 ) for receiving the single primary color and then reflecting the single primary color to the output; one on another exit side of the dichroic mirror ( 24 ) arranged first polarization component ( 26 ) for receiving and then polarizing the dual primary colors; one on an output side of the reflection prism ( 25 ) arranged second polarization component ( 27 ) to receive the single primary color and then polarize the single primary color; one on the first polarization component ( 26 ) arranged dichroic component ( 28 ) for receiving and splitting the dichroic primary color, wherein the reflection prism ( 25 ), the first polarization component ( 26 ), the second polarization component ( 27 ) and the dichroic component ( 28 ) are combined into a Z-shaped prism module; one on the second polarization component ( 26 ) and the dichroic component ( 28 ) arranged modulation device ( 29 ) for receiving, modulating in another polarization state and then reflecting to output the dual primary colors and the single primary color; and one on the first polarization component ( 26 ) arranged projection lens ( 33 ) for receiving the modulated dual and single primary colors and projecting outward onto a display screen. A liquid crystal projection system according to claim 1, wherein the λ / 2 retardation plate ( 34 ) between the dichroic mirror ( 24 ) and the reflection prism ( 25 ) is arranged. A liquid crystal projection system according to claim 1, wherein the reflection prism ( 25 ) is a triangular reflection prism. A liquid crystal projection system comprising: a light source ( 21 ) for emitting a white light; a polarization component ( 22 ) for polarizing the white light to produce a polarized light; a dichroic mirror ( 24 ) for receiving the polarized light and dividing the polarized light into dual primary colors and a single primary color for output; one in the dichroic mirror ( 24 ) arranged λ / 2-delay plate ( 34 ); one on an exit side of the dichroic mirror ( 24 ) arranged polarizing beam splitter ( 23 ) for receiving and polarizing the single primary color for output; one on another exit side of the dichroic mirror ( 24 ) arranged first polarization component ( 26 ) for receiving and then polarizing the dual primary colors; one on an output side of the polarizing beam splitter ( 23 ) arranged second polarization component ( 27 ) to receive the single primary color and then polarize the single primary color; one on the first polarization component ( 26 ) arranged dichroic component ( 28 ) for receiving and splitting the dichroic primary color, wherein the polarizing beam splitter ( 23 ), the first polarization component ( 26 ), the second polarization component ( 27 ) and the dichroic component ( 28 ) are combined into a Z-shaped prism module; one on the second polarization component ( 27 ) and the dichroic component ( 28 ) arranged modulation device ( 29 ) for receiving, modulating in another polarization state, and then reflecting the dual primary colors and the single primary color; and one on the first polarization component ( 26 ) arranged projection lens ( 33 ) for receiving the modulated dual and single primary colors and projecting outward onto a display screen. A liquid crystal projection system according to claim 4, wherein the λ / 2 retardation plate ( 34 ) between the dichroic mirror ( 24 ) and the polarizing beam splitter ( 23 ) is arranged. A liquid crystal projection system according to claim 1 or 4, wherein the λ / 2 retardation plate ( 34 ) between the dichroic mirror ( 24 ) and the first polarization component ( 26 ) is arranged. A liquid crystal projection system according to claim 4, wherein the polarizing beam splitter ( 23 ) is a triangular polarizing beam splitter. A liquid crystal projection system according to claim 1 or 4, wherein the first polarization component ( 26 ) is a polarizing beam splitter. A liquid crystal projection system according to claim 1 or 4, wherein the second polarization component ( 27 ) is a polarizing beam splitter. A liquid crystal projection system according to claim 1 or 4, wherein the dichroic component ( 28 ) is a dichroic prism. A liquid crystal projection system according to claim 1 or 4, wherein the modulation device ( 29 ) a first reflection type liquid crystal panel ( 30 ), a second reflection type liquid crystal panel ( 31 ) and a third reflection type liquid crystal panel ( 32 ), wherein the first reflection type liquid crystal panel ( 30 ) on the second polarization component ( 27 ) and the second reflection type liquid crystal panel (FIG. 31 ) and the third reflection type liquid crystal panel ( 32 ) on one side of the dichroic component ( 28 ) are arranged. A liquid crystal projection system according to claim 1 or 4, wherein a polarizing plate ( 36 ) and a wavelength-selective polarizing plate ( 36a ) between the first polarization component ( 26 ) and the projection lens ( 33 ) are arranged.