JPH032790A - Color display device - Google Patents

Abstract

PURPOSE:To obtain sufficient image resolution and to miniaturize a device by supplying a video signal to a one-dimensional light emitting array and displaying one image stored in plural memories for two-dimensional display data in color. CONSTITUTION:By making readout address supplied to the memories for two-dimensional display data 15R, 15G and 15B corresponding to plural colors different from one another, the image data of the respective colors are read out from the respective memories 15R, 15G and 15B and the respective video signals obtained from the image data are respectively supplied to the one-dimensional light emitting arrays 17R, 17G and 17B to be developed into the two-dimensional image by performing scanning with light from the light emitting arrays 17R, 17G and 17B. The obtained images of the respective colors are composited and displayed in color. Furthermore, the deviation of the images of the respective colors caused by difference between positions where the one-dimensional light emitting arrays are attached is corrected by making the read-out addresses supplied to the memories 15R, 15G and 15B different from one another. Thus, distinct color display is accomplished and the entire device is miniaturized.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a color display device that displays a two-dimensional color image using a one-dimensional light emitting array.

(Summary of the Invention) The present invention relates to a color display device that displays a two-dimensional color image using a one-dimensional light emitting array, and includes a plurality of two-dimensional display data memories each storing image data of a plurality of colors; a plurality of one-dimensional light emitting arrays corresponding to colors;
a first scanning means for sequentially causing a one-dimensional light emitting array to emit light;
a second scanning means for scanning light from the one-dimensional light emitting array in a direction orthogonal to the first scanning direction; and a second scanning means for scanning the light from the one-dimensional light emitting array in a direction orthogonal to the first scanning direction; The one-dimensional light-emitting array is installed by providing an address/offset means for shifting each color according to the positional deviation, and transmitting a video signal obtained from the image data read from the two-dimensional display data memory to the one-dimensional light-emitting array. Supply and above? ! A clear color image is obtained by color displaying one image stored in a number of two-dimensional display data memories.

[Conventional technology]

Conventionally, a cathode ray tube (CRT), a liquid crystal, or a light emitting diode (LED) arranged two-dimensionally has been used as a display device. Incidentally, the display device using the above CRT is relatively large, and as a small display device, one in which liquid crystals and LEDs are arranged two-dimensionally is used.

[Problem to be solved by the invention] By the way, a device in which LEDs are arranged two-dimensionally (two-dimensional L
When configuring a small display device, such as a head amplifier display, using an LED array (ED array), monochrome display is not possible due to restrictions on the external dimensions of the device, and if color is used, it is necessary to use LEDs that correspond to the three primary colors. It is necessary to arrange them two-dimensionally, and the number of LED elements increases, resulting in an excessively large external dimension of the color display device. Furthermore, in order to obtain a display device of the same size as a monochrome display device, it was necessary to lower the resolution and reduce the number of LED elements in the two-dimensional LED array.

The present invention has been made in view of the above-mentioned circumstances, and
Using a one-dimensional light-emitting array with a small number of light-emitting elements such as an ED, the mounting of the one-dimensional light-emitting array element eliminates misalignment of images of each color due to differences in position, has sufficient resolution, and is a compact color display device. The purpose is to provide.

[Means to solve the problem]

A color display device according to the present invention includes a plurality of two-dimensional display data memories each storing image data of a plurality of colors, and a plurality of one-dimensional light emitting arrays corresponding to the plurality of colors.
a first scanning means for sequentially causing the one-dimensional light emitting array to emit light; a second scanning means for scanning light from the one-dimensional light emitting array in a direction perpendicular to the first scanning direction;
The mounting of the one-dimensional light emitting array in the second scanning direction is provided with an address offset means for shifting the reading address of the image data from the memory for dimensional display data for each color according to the positional deviation, and the two-dimensional display By supplying a video signal obtained from the image data read from the data memory to the one-dimensional light emitting array, one image stored in the plurality of two-dimensional display data memories is displayed in color. That's what I did.

[Effect]

In the color display device according to the present invention, image data of each color is read out from each two-dimensional display data memory by differentiating read addresses supplied to two-dimensional display data memories corresponding to a plurality of colors, and these image data are read out from each two-dimensional display data memory. Each image signal obtained from
It is developed into a dimensional image, and the resulting images of each color are combined to display a color display. Furthermore, by differentiating the readout addresses supplied to the two-dimensional display data memory as described above, the mounting of the two-dimensional light emitting array corrects the deviation of images of each color due to the difference in position.

〔Example〕

An embodiment of a color display device according to the present invention will be described below with reference to the drawings.

FIG. 1 is a block circuit diagram of an embodiment of a color display device according to the present invention. In this figure, a so-called pixel clock inputted from a terminal 1 is supplied to a Y counter 11, and in this Y counter 11, the frequency is divided into the period of the Y address of each display data memory area 5R, 15G, 15B, which will be described later.

This frequency-divided signal is supplied as a Y address to the display data memory 15R1, the display data memory 15G, and the display data memory 15B. Also, this Y address is
The signal is supplied to the counter 12, where the frequency is divided by, for example, 1/240. This frequency-divided signal is supplied to the display data memory 15R as an X address. Further, this frequency-divided signal is sent to adders 14G, 14
B is supplied. In the adder 14G, it is added to the first offset X1 supplied from the terminal 2, and in the adder 14B, it is added to the second offset X2 supplied from the terminal 3. These added signals are sent to the display data memory 15G and the display data memory 15B.
Each is supplied as an address. By the way, the respective display data memories 15R, 115C; and 15B contain digitized image data of the three primary colors corresponding to so-called one frame (one screen), that is, R (red) image data, G (
Green) image data and B (blue) image data are stored, respectively, and are read out after controlling the X address and Y address.

Each image data read from each display data memory 15R, 15G, 15B is transferred to a D/A converter 16R116G,
16B, respectively. These D/A converters $
In 16R116G and 16B, each image data is converted into RlG and B signals which are analog signals. These R, G, and B signals are generated by, for example, a light emitting diode (LED).
is supplied to the one-dimensionally arranged LED arrays 17R, 17G, and 17B, respectively. These LED array 17R, LED array 17G
, , R, G in the LED array 17B.

The B signal is converted into red light, green light, and blue light, respectively. These lights are reflected by a mirror 20 for developing the light from the one-dimensional light emitting array into a two-dimensional image, and are incident on the human eye 21. As a result, a color image can be seen. By the way, the above LE
D array 17R1 LED array 17G, LED array 1
7B is controlled by the Y address from the X counter 11, and the mirror 20 is controlled by the X address from the 19.

Here, from reading image data from display data memories 15R115G and 15B to LED arrays 17R and 1
Part 2 for details on how light is emitted in 7G and 17B.
This will be explained using the diagram and FIG.

FIG. 2 shows each display data memory 15R, 15G.

This shows the number of memory cells of 15B. Each display data memory 15R115G, 15B is, for example, a RAM (
It has a configuration in which random access memory) and dual port memory are arranged two-dimensionally. Here, as shown in this figure, the direction in which the Y address increases is defined as the main scanning direction, and the direction in which the X address increases is defined as the sub-scanning direction. Figure 3 shows LED array 17R and LED array 17G.
, a specific arrangement of the LED elements of the LED array 17B is shown, and each LED array 17R117G, 17B has a configuration in which, for example, 240 LED elements are arranged linearly in the main scanning direction. That is, the number of memory cells in the main scanning direction of each display data memory 15R115G, 15B and the number of LED elements of each LED array 17R117G, 17B are the same, and each display data memory 15R11
5G, 15B, the Y address is increased by 1 and the image data is sequentially read out (indicated by the solid arrow)
Main scanning light emission is performed in which the LED elements of each D array 17R, 17G, and 17B sequentially emit light in synchronization with . In addition, each of the above LED arrays 17R, 17
Number of LED elements of G, 17B and memory 1 for each display data
5R,,15G.

The resolution may be increased by setting the number of 15B memory cells in the main scanning direction to, for example, 480.

Next, referring to FIG. 4, an explanation will be given of a sub-running readout operation in which the main readout operation is sequentially performed by incrementing the X address by 1 as shown in FIG. FIG. 4 shows a time chart of image data obtained by sub-scanning readout. In this figure, for the X address supplied to the display data memory 15R, the display data memory 1
The X address supplied to 5G is the first offset
The X address supplied to the display data memory 15B is advanced by the second offset X2.

That is, when the R image data of the memory cell whose X address is specified by, for example, Xo is being read in the display data memory 15R, the memory cell whose 6 image data are read out and stored in the display data memory 15B.
In , 8 image data of the memory cell whose X address is designated by X, +XZ is read out. Each image data read out in this way is transferred to the D/A converter 16R116.
It is converted into an analog signal in G and 16B, and is supplied to the LED arrays 17R, 117G and 17B, respectively. Incidentally, the mirror 20 is driven by the mirror drive circuit I9 in synchronization with the sub-scanning readout in which the X address is incremented by 1 and read out sequentially, and optical scanning (sub-scanning) by the mirror 20 is performed. As a result, LED array 17R
The one-dimensional images from 117G and 17B are developed on a two-dimensional plane. By the way, since the mounting positions of the LED arrays 17R, 17G, and 17B in the sub-scanning direction are different, when the image is developed on a two-dimensional plane, the R screen that is formed,
It is normal for the 0 screen and 8 screen to be shifted, but the sizes of the above offsets Xl and X2 should be set according to the installation interval of each LED array, and the display data memory 15R should be set as described above. By advancing the X address supplied to the display data memory 15G by an offset X1 and advancing the X address supplied to the display data memory 15B by an offset X2 with respect to the supplied X address,
It is possible to match each image of the R screen, 0 screen, and 8 screen.

As described above, the sub-scan reading of image data from the display data memory and the optical scanning by the mirror are synchronized, and the mounting of each LED array is offset to the readout X address of the display data memory depending on the position. By having , it is possible to display a two-dimensional image in color without color shift even if the images of the three primary colors stored in each display data memory are combined. Note that by repeating the reading of all stored image data and optical scanning at the so-called field frequency,
Still images stored in the display data memory can be displayed in color. In addition, by storing moving images from a video device such as a video recorder in the display data memory in accordance with the field frequency, and reading out the moving images in accordance with the field frequency,
It is also possible to display videos. Further, by changing the number of memory cells in the X address direction of the display data memory and the width of the optical scan of the mirror 20, a screen with an arbitrary aspect ratio can be constructed.

It should be noted that the present invention is not limited to the above-mentioned embodiments, but the LED arrays 17R, 17G, and 17B may be arranged in three rows each like the LED arrays 22R, 122G, and 22B shown in FIG. 5 to increase the resolution. Good too. Also, mirror 20
It is also possible to use a half mirror to take in the external field of view. In addition, the mirror 20 is replaced with a polygon mirror 31 as shown in FIG. 6, and sub-scanning is performed by rotationally driving the polygon mirror 31, and display is performed through a cylindrical lens 32, thereby suppressing vibrations caused by the operation of the mirror. be able to. Alternatively, the mirror 20 may be a polygon mirror 41 as shown in FIG. 7, and the light reflected by the concave mirror 42 may be displayed. Further, the present invention may be applied to a three-dimensional color display device, a large field of view display device, a projector, etc.

〔Effect of the invention〕

As is clear from the above description, in the color display device according to the present invention, the image data is supplied to the two-dimensional display data memory corresponding to a plurality of colors by different reading addresses. By correcting the misalignment of the images of each color due to the difference in position of each one-dimensional light emitting array, it is possible to eliminate the misalignment of the images of each color and provide clear color display. Furthermore, by using a one-dimensional light-emitting array that has several hundredths of the number of light-emitting elements compared to a two-dimensional light-emitting array, the entire color display device can be made smaller. Furthermore, since the number of LED elements is small, the device is inexpensive and has high yield and reliability.

2-X counter 4 R, 14G-1 adder 5R115G, 15B-・Display data memory 7R, 1
7G, 17B--LED array 〇-Optical scanner mirror 2R122G, 2213-L E D array 1.41-
optical scanner polygon mirror

[Brief explanation of the drawing]

FIG. 1 is a block circuit diagram of an embodiment of a color display device according to the present invention, FIG. 2 is a diagram showing a memory map of a display data memory, FIG. 3 is a plan view showing the arrangement of an LED array, and FIG. 4 is a diagram showing a memory map of a display data memory. is a time chart of image data read out from the display data memory, FIG. 5 is a plan view showing another arrangement of the LED array, and FIGS. 6 and 7 are optical scanners used in the color display device according to the present invention. It is a figure which each shows the other structure of.

Claims (1)

[Scope of Claims] A plurality of two-dimensional display data memories each storing image data of a plurality of colors, a plurality of one-dimensional light emitting arrays corresponding to the plurality of colors, and sequentially causing the one-dimensional light emitting array to emit light. a first scanning means; a second scanning means for scanning light from the one-dimensional light emitting array in a direction perpendicular to the first scanning direction; and an address for reading image data from the two-dimensional display data memory. and an address offset means for shifting the image data for each color according to the deviation of the mounting position of the one-dimensional light emitting array in the second scanning direction, the image data being obtained from the image data read from the two-dimensional display data memory. A color display device, characterized in that a video signal is supplied to the one-dimensional light emitting array, and one image stored in the plurality of two-dimensional display data memories is displayed in color.