KR950007038B1 - Lens system for l.c.d. projector - Google Patents

Abstract

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Description

LCD projector optical system

1 is an optical system configuration of a conventional LCD projector.

2 is a view of a conventional LCD projector optical system light control unit.

3 is a, b, c, d is a diagram showing the various polarization state appearing in the light control unit of FIG. 2, a is an arbitrary polarization state, b is a first linear polarization state diagram, c is an elliptic polarization state diagram, d Is a second linear polarization state diagram.

4 is a configuration diagram of an LCD projector optical system according to the present invention.

5 is a view showing the progress of the polarization state of the polarization control unit of the present invention.

Figure 6 is a functional diagram showing a process of changing the P-wave polarization state to the S-wave polarization state in the polarization control unit of the present invention.

7 is a configuration diagram showing another embodiment of the LCD projector optical system according to the present invention.

* Explanation of symbols for main parts of the drawings

1: Lamp 2: Reflector

4 liquid crystal panel 5 polarizer

6: Projection lens 7: Screen

10: polarization control unit 11: collimator (Collimator)

12 λ / 4-plate 13 S / P wave polarization separation prism

14: reflector 15,16: first, second reflector

A: light source S: video signal

The present invention relates to an LCD system (Liquid Crystal Display Projector) optical system, and more particularly to an LCD projector optical system to maximize the light utilization efficiency to increase the sharpness of the screen.

The conventional general LCD projector optical system is composed of a lamp (1) for emitting white light and a reflector (2) for reflecting forward light emitted to the rear, as shown in FIGS. The first polarizing plate 3 and the first polarizing plate 3 which transmit only linearly polarized light in one direction α of the light source unit A and the white light reflected by the light source unit A in an arbitrary polarization state and absorb the remaining light. LCD panel 4 which changes the linearly polarized light passing through) into an elliptical polarization state according to the voltage of the applied video signal S and a predetermined direction (α + π) from the light of the elliptical polarization state. And a second polarizing plate 5 which transmits only linear flatness of light (2) and absorbs the remaining light, and implements the image information of the video signal 5 as an image on the emission-side surface of the second polarizing plate 5 as an image control unit B. ) And the image formed by the light control unit (B) on the screen And a projection lens 6 for magnifying and projecting onto the projection lens, and a screen 7 for reflecting or transmitting the light projected by the projection lens 6 to form an image.

The conventional LCD projector optical system configured as described above emits red, green, and blue white light from the lamp 1 of the light source unit A in an arbitrary polarization state as shown in Fig. 3A, and enters the light control unit B. do.

The white light of any polarization state incident as described above is transmitted by the first polarizing plate 3 of the light control unit B, and only linearly polarized light in one direction α is transmitted as shown in (b) of FIG. 3, and the remaining light is absorbed. do.

The linearly polarized light in a predetermined direction passing through the first polarizing plate 3 is transmitted through the liquid crystal panel 4. In this case, the liquid crystal array of the liquid crystal panel 4 is linearly changed by the voltage of the video signal S applied thereto. The light in the polarization state is changed into an elliptical polarization state as in (c) of FIG. 3 and is incident on the second polarizing plate 5.

As described above, in the incident elliptical polarization light, only the linearly polarized light in a specific one direction (α-π / 2) is transmitted by the second polarizing plate 5, and the remaining light is absorbed.

In the above-described process, the image information of the video signal S is realized as an image on the output side surface of the second polarizing plate 5, and is projected to the screen 7 by the projection lens 6 to be colored on the screen 7. The image is implemented.

However, in the conventional LCD projector optical system as described above, only a part of red, green, and blue white light emitted from the lamp 1 of the light source unit A in an arbitrary polarization state and incident on the light control unit B (specific one direction) The linear polarization of (α) is transmitted by the first polarizing plate 3 and the remaining light is absorbed, resulting in a very low light utilization efficiency (less than 50%).

As such, the conventional LCD projector optical system has a problem of deterioration in image quality due to low light utilization efficiency.

In view of this, an object of the present invention is to employ a polarization control unit that linearly polarizes all the light emitted from the lamp in one direction, so that all the light emitted from the lamp is incident on the liquid crystal panel while maintaining the S-wave polarization state. It is to provide an LCD projector optical system that maximizes efficiency.

In order to achieve the object of the present invention as described above, a light source unit consisting of a lamp and a reflector for emitting white light, a polarization control unit for linearly polarizing all of the light emitted from the lamp of the light source unit in one direction, and linearly flattened by the polarization control unit A liquid crystal panel which changes into a p-polarized polarization state according to a voltage of a video signal to which light is applied, a polarizing plate which transmits only linear polarization in one direction among elliptically polarized light by the liquid crystal panel to implement image information of a video signal into an image; And a projection lens for magnifying and projecting the image onto a screen, and a screen for forming an image by reflecting or transmitting the light projected by the projection lens.

The polarization control unit collimator for irradiating the light emitted from the lamp in parallel, a retardation member for changing the polarization state of the incident light, and the wavelength of the incident light is transmitted to transmit the light of the S-wave polarization state and P-wave polarization state The S / P wave polarization separation prism reflecting light and the reflector plate reflecting the light of the P wave polarization state reflected by the S / P wave polarization separation prism have all the light emitted from the lamp. It is configured to be incident on the liquid crystal panel while maintaining the state.

The polarization control unit may further include a retardation member for changing a polarization state of incident light, an S / P wave polarization separation prism for separating S wavelengths of light passing through the retardation member, and transmitting S waves and reflecting P waves; Another embodiment is provided, which is composed of a first member and a second reflector provided on the upper side and the lower side of the dating member and the S / P wave polarization separation prism.

The retardation member is composed of a λ / 4-plate.

The LCD projector optical system according to the present invention can maximize the utilization efficiency of light by linearly polarizing all of the light emitted from the lamp in one direction and entering the liquid crystal panel, thereby increasing the sharpness of the screen.

Hereinafter, the LCD projector optical system according to the present invention as described above will be described in more detail with reference to the accompanying drawings.

4 is a configuration diagram of the LCD projector optical system according to the present invention, as shown in the present invention, in the LCD projector optical system, the lamp (1) for emitting white light and the reflector for reflecting light emitted backward (forward) In front of the light source unit (A) consisting of 2) to install a polarization control unit 10 for transmitting and transmitting all the light emitted from the lamp 1 in a linear polarization state, it is configured to maximize the light utilization efficiency .

The polarization control unit 10 includes a collimator 11 for irradiating the light emitted from the lamp 1 in parallel, a λ / 4-plate 12 for changing the polarization state of the incident light, and the incident light. S / P wave polarization separation prism 13 having a transmission reflector 13a for separating wavelengths (S wave and P wave) to transmit light in S wave polarization state and reflect light in P wave polarization state, The liquid crystal panel is provided with a reflector 14 which reflects light of the P-wave polarization state reflected by the S / P-wave polarization separation prism 13 so that all light emitted from the lamp 1 maintains the S-wave polarization state. Configured to be incident on (4).

At this time, the focus of the collimator 11 is matched to the light emitting source of the lamp 1, the reflector 2 of the light source unit A is semi-circular, so that the center of the reflector 2 is the light emitting source of the lamp 1 do. In addition, the liquid crystal panel 4 in front of the polarization control unit 10 changes the light of the linear polarization state passing through the polarization control unit 10 to an elliptical polarization state according to the voltage of the video signal S applied thereto, and an ellipse. Polarizing plate 5 which transmits only light of a linear polarization state in a predetermined direction and absorbs the remaining light among polarized light, and implements image information of video signal S as an image, and projection for projecting the image on a screen. The lens 6 and the screen 7 for forming an image by reflecting or transmitting the light projected by the projection lens 6 are sequentially rearranged.

In the drawings, the same reference numerals are given to the same parts as in the prior art.

5 is a functional diagram showing the progress of the polarization state of the polarization control unit of the present invention, Figure 6 is a functional diagram showing a process of changing the light of the P wave polarization state to the light of the S wave polarization state in the polarization control unit of the present invention, Subscript P ₁ represents light in any polarization state, P ₂ represents light in P-wave polarization state, P ₃ represents light in S-wave polarization state, P ₄ represents clockwise circularly polarized light, and P ₅ counterclockwise direction will shown the light of circular polarization, P ₆ is converted into an S wave polarization state for the light of the P-wave polarization state is reflected by the S / P-wave polarization splitting prism 13, passes through the reflection and re-reflected S / The light of the second S-wave polarization state passing through the P-wave polarization separation prism 13 is shown.

Hereinafter, referring to FIG. 4 and FIG. 5 and FIG. 6, the operation effects of the LCD projector optical system according to the present invention will be described.

First, the light emitted by the lamp 1 of the light source unit A is paralleled by passing through the collimator 11 to pass the S / P wave through the λ / 4-plate 12 in an arbitrary polarization state P ₁ . The incident light is incident on the polarization split prism 13, and the incident light is separated into wavelengths of S waves and P waves, and the light P _{3 in an} S wave polarization state is transmitted to enter the liquid crystal panel 4, and P waves The light P _{2 in the} polarization state is reflected vertically downward by the transmission reflector 13a.

The reflected light P ₂ in the P-polarized state is reflected back to the S / P-wave polarization splitting prism 13 by the reflector 14, and the λ / 4-plate 12 is transmitted by the transmission reflector 13a. Is incident on and maintained as light P ₄ in a clockwise circularly polarized state.

Such clockwise circularly polarized light P ₄ is reflected by the reflector 2 of the light source unit A through the collimator 11 and at the same time maintained as light P _{5 in} the counterclockwise circularly polarized state λ. / 4- plate 12 is reincident.

As described above, the light P ₅ of the counterclockwise circularly polarized state reentered into the λ / 4-plate 12 passes through the second S-wave circular polarized state P while passing through the λ / 4-plate 12. ₆ ) to pass through the S / P wave polarization separation prism 13 and enter the liquid crystal panel 4.

In other words, all the light emitted from the lamp 1 is incident to the liquid crystal panel 4 while maintaining the S-wave polarization state without loss, thereby maximizing light utilization efficiency.

On the other hand, the light incident on the liquid crystal panel 4 by the above process is converted into an elliptical polarization state according to the voltage of the video signal S applied by the action of the liquid crystal panel 4, the action of the polarizing plate 5 It is implemented as an image, and the image thus implemented is projected on the screen 7 by the projection lens 6 to enlarge and form a brighter color image on the screen (7).

As described in detail above, the LCD projector optical system according to the present invention installs a polarization control unit for injecting all the light emitted from the lamp into the liquid crystal panel in a linear polarization state in one direction in front of the light source, so that all the light emitted from the lamp is S-wave. Since it is incident on the liquid crystal panel without loss while maintaining the polarization state, the utilization efficiency of light can be maximized, and accordingly, a clearer screen can be obtained.

7 is a configuration diagram showing another embodiment of the LCD projector optical system according to the present invention, as shown in another embodiment of the present invention in the configuration of the polarization control unit 10, the light emitted from the lamp 1 S / P wave polarization separation prism 13 which separates the λ / 4-plate 12 which changes the polarization state and the wavelength of light passing through the λ / 4-plate 12 and transmits the S wave and reflects the P wave. ) And the first and second reflectors l5 and 16 provided on the upper and lower sides of the λ / 4-plate 12 and the S / P wave polarization separation prism 13, and constitute other optical systems. Since the other configurations and operation effects are similar to the above-described embodiment, the same components are assigned the same reference numerals, and detailed descriptions thereof will be omitted.

Claims (4)

A light source unit A consisting of a lamp 1 and a reflector 2 emitting white light, and a polarization control unit for controlling and transmitting all light emitted from the lamp 1 of the light source unit A in a linear polarization state in one direction ( 10), the liquid crystal panel 4 for changing the linearly polarized light by the polarization control unit 10 into an elliptical polarization state according to the voltage of the video signal S applied thereto, and an ellipse by the liquid crystal panel 4 Polarizing plate 5 which transmits only linear polarization in one direction among polarized light to implement image information of video signal S as an image, a projection lens 6 for enlarging and projecting the image on a screen, and the projection lens 6 And a screen (7) for reflecting or transmitting the projected light to form an image. According to claim 1, wherein the polarization control unit 10 is a collimator 11 for irradiating the light emitted from the lamp 1 in parallel, a retardation member for changing the polarization state of the incident light, the wavelength of the incident light P / S polarized light separating prism 13 which transmits light in S-wave polarization state and reflects light in P-wave polarization state, and P wave reflected by S / P wave polarization separating prism 13 LCD projector optical system, characterized in that consisting of a reflecting plate (14) for re-reflecting light in a polarized state. The S / P of claim 1, wherein the polarization control unit 10 separates a retardation member for changing the polarization state of incident light from a wavelength of light passing through the retardation member, and transmits S waves and reflects P waves. LCD projector comprising a wave polarization separation prism (13), and first and second reflectors (15, 16) disposed above and below the retardation member and the S / P wave polarization separation prism (13). Optical system. 4. The LCD projector optical system according to claim 2 or 3, wherein the retardation member is lambda / 4-plate (12).