JPH0358016A - Display device - Google Patents

Abstract

PURPOSE:To simplify the structure of a liquid crystal cell and to obtain a bright display image by fixing one end of an optical fiber at a position corresponding to each liquid crystal shutter of the liquid crystal cell and forming a display part at the other end. CONSTITUTION:Liquid crystal cells 3 which have independent liquid crystal shutters 4 provided in dots are arranged on the light emission surfaces of chro matic light sources 1a-1c for display. One end of each optical fiber 6 is fixed at a position on the opposite surface of each liquid crystal cell 3 from the light source corresponding to each liquid crystal shutter 4 and the display part 8 is formed on the other end side. Then the respective liquid crystal shutters 4 of the liquid crystal cell 3 are controlled with an image signal to display a dot image on a display part. Therefore, one liquid crystal cell 3 is put in charge of only one color, so the cell structure can be simplified and the opening area of the liquid crystal shutter 4 is increased to obtain the bright display image.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a display device that combines a liquid crystal shutter and an optical fiber.

[Conventional technology]

Conventionally, as a display device using a liquid crystal cell, a device in which a plurality of liquid crystal shutters are provided in the liquid crystal cell in a dot pattern and each liquid crystal shutter is driven according to an image signal to display a desired image is known. It is being Here, the arrangement of each liquid crystal shutter of the liquid crystal cell is the same arrangement as the display dots of the display section, so that an image is formed on the liquid crystal cell. It is also possible to enlarge the displayed image using an optical fiber or the like.

(Problem to be Solved by the Invention) A display device using a conventional liquid crystal cell is configured as described above, and since the arrangement of each liquid crystal shutter is the same as the display dot, the structure of the liquid crystal cell is However, since the liquid crystal shutter cannot have a large aperture area, it is not possible to obtain a bright display image.

This invention was made to solve these problems, and aims to provide a display device that can simplify the structure of a liquid crystal cell and provide a bright display image. (Means for Solving the Problems) A display device of the present invention is configured as follows.

a. A liquid crystal cell having a plurality of independent liquid crystal shutters arranged in a dot pattern is arranged on the light emitting surface of a light emitting light source for display, and a position corresponding to each liquid crystal shutter on the surface of the liquid crystal cell opposite to the light emitting light source is arranged. One end of each optical fiber is fixed to each, and a display section is formed on the other end side of these optical fibers, and each liquid crystal shutter of the liquid crystal cell is controlled by an image signal to display a dot image on the display section. I made it.

b. In the display device of item a above, the light emitting sources are red. green. It has colored light sources that emit light in the three primary colors of blue, and three optical fibers from each colored light source are used as a set to constitute each display dot of the display section to display a full-color image.

C. In the display device a or b above, a ferroelectric liquid crystal was used in the liquid crystal cell.

(Function) In the display device of the present invention, one end of the optical fiber is fixed at a position corresponding to each liquid crystal shutter of the liquid crystal cell, and the C display section on the other end side of the optical fiber is formed. The cells only need to share image signals of one color, and the arrangement of each liquid crystal shutter can be selected.

(Embodiment) FIG. 1 is a configuration diagram showing a main part of a display device according to an embodiment of the present invention. In the figure, la, lb, and lc are respectively R (red). G (edge). These are colored light sources that emit light in the three primary colors of B (blue), and are housed in each lamp house 2. Furthermore, a liquid crystal cell 3 using ferroelectric liquid crystal is arranged on the light emitting surface of these colored light sources 1a, lb, and lc. This liquid crystal cell 3 is provided with a plurality of independent liquid crystal shutters 4 in the form of dots, each of which corresponds to each liquid crystal shutter 4 on the side opposite to the colored light sources 1a, lb, lc of the liquid crystal cell 3. One end of a plurality of optical fibers 6 each attached to a fiber assembly 5C is fixed at the position, and a fiber display section 8 consisting of a large number of display dots 7 is formed on the other end side of these optical fibers 6. That is, each display dot 7 of the display section 8 is constructed by using a set of three optical fibers 6 from each of the colored light sources 1a, lb, and lc.゛In addition, a driving IC 9 connected to a control circuit (not shown) through a connector 10 is attached to each of the liquid crystal cells 3, and each liquid crystal shutter 4 is controlled via this driving IC 9, thereby controlling the display. A desired full color image is displayed in dots in section 8.

FIG. 2 is a view of the display section 8 viewed from the front, and as shown in the figure, end surfaces 6a of three R, G, and B optical fibers 6 are fixed to each display dot 7. Further, FIG. 3 shows a part of the structure of the liquid crystal cell 3, and each liquid crystal shutter 4 is formed in a dot shape as described above.

Note that the arrangement of the liquid crystal shutters 4 does not have to be the same as the arrangement of the display dots 7 of the display section 8.

Figure 4(a). (b) is a plan view and a side view showing an example of the overall configuration of the liquid crystal cell 3. A large number of liquid crystal shutters 4 are divided into groups, and a driving IC 9 and a connector 10 are attached to each group.

Next, the operation will be explained.

Each light source 1a. The light emitted from the lb and lc passes through each liquid crystal shutter 4 in a liquid crystal cell 3 using ferroelectric liquid crystal, and is guided to a display section 8 via an optical fiber 6. At this time, each liquid crystal shutter 4 is configured to be able to independently change the amount of light transmitted by the gradation signal from the driving IC 9, and this control is performed from an external control circuit via the driving IC 9. As the control signal (image signal) from the control circuit, a video signal or an output signal from a microcomputer is selected depending on the purpose. The island surface 6a of each optical fiber 6 is focused on a display section 8, and the R, G, and B lights are mixed at each display dot 7, and a desired image according to the signal from the control circuit is displayed in full color. is displayed as a dot.

Here, the display dots 7 of the display section 8 are arranged in an order in which an optical image is formed according to the image signal from the control circuit, but the arrangement of the liquid crystal shutters 4 in the liquid crystal cell 3 does not necessarily correspond to the display dots. It does not have to be the same arrangement as 7, and can be freely selected depending on the arrangement of the output terminals of the driving IC 9, etc., for example. In this case, adjustment of the difference between the arrangement of the liquid crystal shutters 4 and the arrangement of the display dots 7 is achieved by changing the route of the optical fiber 6 that connects them.

That is, there is no need to form an image on the liquid crystal cell 3,
Since the image can be formed on the display 11S8 by changing the route of the optical fiber 6, one liquid crystal cell 3 only needs to share one color of image signal, and the structure of the liquid crystal cell 3 can be simplified. The aperture area of each liquid crystal shutter 4 can be made large, and a bright display image can be obtained using the thick optical fiber 6. Further, since there is no need to provide a color filter, the structure of the liquid crystal cell 3 is simplified accordingly, and the liquid crystal cell 3 can have a relatively large area. Furthermore, by making the arrangement interval of the display dots 7 larger than the arrangement interval of the liquid crystal shutter 4, an enlarged image can be easily obtained. By combining a large number of liquid crystal cells 3,
It is also possible to display on a large screen without any seams.

Moreover, the colored light sources 1a, lb. Since the emitted color of the LC appears on the display section 8 as it is, by changing the emitted color, you can easily change the hue of the display screen.Furthermore, if you use a light source with a large amount of light, you can achieve higher brightness. A display screen is obtained.

In the above embodiment, the colored light sources 1a. ! Although we have shown the case of full color display using B and LC, it is also possible to obtain a monochrome display screen with one light emitting light source, and it is also possible to display a black and white (monochrome) pattern using a white light source. .

In addition, in the above embodiment, since a ferroelectric liquid crystal is used for the liquid crystal cell 3, the liquid crystal shutter 4 can be opened and closed at high speed, and the amount of light transmitted can be changed using a gradation signal. When applied to display, high-quality images can be obtained.

(Effects of the Invention) As described above, according to the present invention, one end of an optical fiber is fixed at a position corresponding to each liquid crystal shutter of a liquid crystal cell,
Since the display section is formed on the other end of the optical fiber, the arrangement of the liquid crystal shutters can be selected, the structure of the liquid crystal cell can be simplified, and the aperture area of the liquid crystal shutter can be increased. This has the effect that a bright display image can be obtained. Furthermore, by using ferroelectric liquid crystal, the liquid crystal shutter can be opened and closed at high speed.

[Brief explanation of drawings]

Fig. 1 is a block diagram showing an embodiment of the present invention, Fig. 2 is a front view of the display unit in Fig. 1 seen from the front, Fig. 3 is a block diagram of the liquid crystal cell in Fig. wi, and Fig. 4 ( a). (b) is a plan view and a side view showing an example of the overall configuration of a liquid crystal cell. 1 a, l b, 1 c.1.1 colored light source 2-1 lamp house 3-1 liquid crystal cell 4-1 liquid crystal shutter 5--fiber assembly 6.1-1 optical fiber 6a-1 end surface 7-1 display dot 8・11 fiber display section 9 ------Drive IC 10/11 connector

Claims (3)

[Claims] (1) A liquid crystal cell having a plurality of independent liquid crystal shutters arranged in dots is arranged on the light emitting surface of the light emitting light source for display, and each liquid crystal shutter on the surface of the liquid crystal cell opposite to the light emitting light source is arranged. One end of each optical fiber is fixed at a corresponding position, a display section is formed on the other end side of these optical fibers, and each liquid crystal shutter of the liquid crystal cell is controlled by an image signal to display a dot image on the display section. A display device characterized by displaying information. (2) Each of the light emitting light sources has a colored light source that emits light of the three primary colors of red, green, and blue, and each display dot of the display unit is configured as a set of three optical fibers from each colored light source,
2. The display device according to claim 1, wherein the display device displays a full-color image. (3) The display device according to claim 1 or 2, wherein a ferroelectric liquid crystal is used for the liquid crystal cell.