JP2648629B2 - Scan type display - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (1) Technical Field of the Invention The present invention moves a linear display having a large number of light emitting element dots arranged in a line relative to an observer, and causes an afterimage of an eye. The present invention relates to an improvement of a scan type display device that allows an image such as a character or a picture to be visually recognized by an effect.

(2) Prior Art Recently, the following scan type display devices have been developed. This type of display uses a linear display in which light-emitting diodes (LEDs) are arranged one-dimensionally.
It displays a striking image using the afterimage effect of the eyes by the relative movement of the observer and the display (Japanese Patent Publication No. 59-58).
No. 96, JP-A-60-196795, JP-A-1-78295, JP-A-2-61693, JP-A-2-89089).

For example, a linear display is installed vertically on the wall of a subway tunnel, and bitmap format image data is sequentially read out from the memory by the display controller in units of lines, and the LED array of the linear display is read in accordance with each line data. It is configured to drive blinking. The display output is performed when the train passes the installation location of the linear display, and the display speed (line data switching cycle) at that time is adjusted according to the speed of the train. When the person on the train looks at the inside and outside of the car, the above-mentioned linear indicator moves at high speed just outside the window. At that time, the LED array of the linear display is blinking according to the image data. Since the person in the car does not follow this linear display (it cannot), the linear display is scanned by the observer in the direction orthogonal to the longitudinal direction, and the observer is affected by the afterimage effect. Will visually recognize the image of the surface.

Also, the above-described linear display is attached to a drive mechanism for rotating the display in a direction orthogonal to the longitudinal direction (rotated by a motor or the like), and the above-described display output control is performed on the rotating display. (Match the display speed to the rotation speed). In this case, even if the observer is stationary, the display is scanned two-dimensionally, so that the image of the surface can be seen due to the afterimage effect.

(3) Problems to be Solved by the Invention A technical problem to be solved by the present invention is to realize a brighter display in the above-mentioned scan type display device. That is, display luminance is improved.

As a means for arbitrarily controlling the LED luminance level, there is a method of changing a current value (amplitude) and a duty ratio of an LED drive pulse, and is employed in various electronic devices. The only way to increase the light emission luminance is to increase the drive current, compared to the case where the duty ratio is 100%.
Even with the use of high-brightness LEDs that are being developed one after another, it is not possible to obtain brightness beyond the limit value inherent to the device.

As another means for increasing the display brightness, there is a method of arranging a plurality of LEDs in proximity to one image dot and causing the plurality of LEDs for one dot to emit light simultaneously. However, in this method, it is inevitable that the area of one pixel dot becomes large, so that another serious problem that the resolution is reduced occurs.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described conventional problems, and has as its object to provide a scan-type display device capable of increasing display luminance without lowering resolution.

(4) Means for Solving the Problems Accordingly, the present invention provides a display array in which a large number of display images are arranged in a line, and sets a relative relationship in which the display array moves in the width direction with respect to an observer. Display control means for supplying the image data to be displayed to the display array in order by a predetermined amount at a speed corresponding to the moving speed and driving the light emission of the display array is provided, and the image of the display array is displayed on the retina of the observer. The following configuration is added to a scanning display device in which a surface is scanned and an image of a surface is made visible by an afterimage effect.

First, the display array is composed of a plurality of display element rows arranged at predetermined intervals in the direction of the movement. Further, the display control means may sequentially arrange the image data with respect to the plurality of display element columns of the display array in the order of the movement with a delay corresponding to the speed of the movement and the interval between the display element rows. It is configured to be supplied to. as a result,
A plurality of display images obtained by scanning the respective display element rows of the display array almost coincide with each other and overlap.

(5) Operation The operation of the present invention will be described with reference to FIG. As shown in FIG. 1 (a), in the case of a display screen composed of L × M pixels, assuming that the aspect ratio is 1: 1 with respect to the element spacing d [m] of the L pixels. , M pixels are also displayed at intervals d. At this time, if the passing speed of the observer is v [m / s],
The display interval time t ₀ of each column is t ₀ = d / v. Hereinafter referred to as that the t ₀ is referred to as a unit time.

In the conventional scanning type advertising pillar device by the display data at t ₀ interval is updated, the eye afterimage effect, the display screen of L × M pixels is obtained. Each row of display elements consists of a sequence display of multiple rows in the present invention shown in FIG. 1 (b) (N columns), the display data in Likewise t ₀ interval and the conventional example is updated, further t ₀ By sending display data to adjacent display element columns at intervals, the display time of the same column data is increased by N times and the luminance level is improved. The observer moves left v as shown in FIG.
When passing at a speed of [m / s], the fixed display element appears to move to the right at a speed of v [m / s] to the observer. In this case, further described in detail in accordance with FIG. 1 (c), there new display data in the n-th column of the time for the display data of n-th column and a at t, then t + t ₀ In the display device after the unit time has elapsed b is displayed, and data a is displayed in the (n + 1) th column. On the other hand, since the observer moves the element interval d during this time, it appears to the observer that the display data a is displayed at the same position twice as long as the conventional display data. Thereafter, the display data is transferred to the next column one after another, so that a display time N times as long as that in the related art can be obtained.

Of course, N may be determined according to a desired luminance level, and it goes without saying that N can be determined independently of the number M of horizontal pixels.

(6) Embodiment One embodiment of the present invention will be specifically described below with reference to FIG. FIG. 3 is an overall block diagram.

The overall circuit is roughly divided into three blocks: a sensor unit, a data generation unit, and a display unit. The sensor unit detects a movement of a vehicle (hereinafter, referred to as a moving object) on which an observer rides, and calculates a moving direction and a moving speed of the moving object by receiving information from the sensor circuit, Judgment unit that sends information that changes the timing signal
Consists of 22. The data generation unit includes a memory unit 24, a parallel-serial conversion unit 25 that converts parallel data output from the memory unit into serial data, and a timing generator 23 that generates an address of the memory unit 24 and generates a control signal for each unit. The display unit receives the data from the data generation unit and converts it into parallel data. The serial-parallel conversion unit 26, the display driver unit 27 that latches the parallel data and drives the display element, the LED, and the EL head blinks at a predetermined scan speed. It comprises a display array unit 28 using an appropriate display element capable of performing the above operations.

FIG. 3 is a detailed block diagram of the display unit. A shift register 30 that converts the serial display data sent from the data generation unit into parallel, and a flip-flop circuit (hereinafter referred to as F / F) that latches the parallel data with a latch clock DLCK.
The latched data 31 drives the display element array 33 by the display driver 32 to obtain the display of the first column. At this time, the data of the F / F31 at the immediately preceding timing is latched in the F / F34, and the display element row is passed through the driver 35.
Displayed by 36. This means that the display data a in the n-th column at the timing t in FIG. 1C is displayed as the data in the n + 1-th column at the timing of t + t ₀ . Similarly, the data latched in the N-th F / F 37 is displayed by the display element array 39 through the driver 38. Here, as described in the operation (5), since the passenger of the moving body is moving the same distance as the interval between the display element rows at the same time as the column data is latched in the adjacent row, the data a is stopped. I can see Therefore, N times of the time data a is displayed as compared with the case where the number of display columns is one.

This operation will be described with reference to the timing chart of FIG. Assuming that the display starts from column 1 of the DDAT data,
It is assumed that data before that is 0. The data DDAT transferred to the shift register by DSCK is
At the timing t1, only the display element column 33 displays the data of the column 1 and the other display elements have the data 0 latched by the F / F at the timing t1, and the display is turned off. By the way, at timing t2, the data in column 1 is F / F34
And the data of column 2 is latched by the F / F 31. Therefore, the column data 2 is displayed on the display element column 33, and the column data 1 is displayed on the display element column 43. Similarly, at timing t3, display element column 1 has column 3, display element column 2
Column 2 and the display element column 3 display the data of column 1.

FIG. 5 is a block diagram of a display unit showing another embodiment. Since there is a standard IC in which a shift register and a flip-flop are included in one package, such a configuration using the shift register has a small amount of wiring and can be easily extended. This is obtained by expanding the space between the columns by inputting the input to the shift register 504 in the column next to the output of the shift register 500, using a circuit similar to the circuit configuration in each column.

In the case of multi-color display, the following will be dealt with. If a multicolor light emitting element in which a plurality of LED chips having different emission colors are mounted on one small lens body is used as the display element, the same configuration as in the case of the single color display may be used. The image data consists of color-specific data for driving the LED chip for each color.
What is necessary is just to supply to D chip simultaneously. When multi-color display is performed using LEDs with lenses that emit different colors, a display array in which a plurality of LEDs with lenses that emit different colors are arranged in a plurality of rows for each color is used. it may be configured to supply sequentially delayed by the time t ₀ the each color data to the lensed LED row of color-coded for.

(7) Effects of the Invention According to the present invention, a plurality of light emitting elements are turned on a plurality of times at a position corresponding to one pixel on a display image with a short time, so that the area of one pixel can be enlarged. Without (without reducing the resolution), the brightness level of the display is improved. Further, according to the same principle, a plurality of light emitting elements having different colors are turned on at a position corresponding to one pixel on a display image after a short time, so that multicolor display can be performed without lowering the resolution.

[Brief description of the drawings]

Drawings show an embodiment of the present invention, FIG. 1 is a diagram showing operation rights, FIG. 2 is a block diagram showing an entire circuit configuration, FIG. 3 is a block diagram showing a circuit configuration of a display unit, 4th
FIG. 5 is a timing chart showing the operation, and FIG. 5 is a block diagram showing a display unit circuit configuration based on the second embodiment. 21: Sensor unit 22: Judgment unit 23: Timing generator unit 24: Memory unit 25: Para-serial conversion unit 26: Serial-parallel conversion unit 27: Display driver unit 28: Display array 29: Data bus unit 30 shift register 31 flip-flop 32 driver 33 display element row 1 34 flip-flop 35 driver 36 display element row 2 37 flip-flop 38 driver 39 display Element row N 500, 504, 508 Shift register 501, 505, 509 Flip-flop 502, 506, 510 Driver 503 Display element row 1 507 Display element row 2 511 Display element row N

Claims (3)

(57) [Claims] A display array in which a large number of display pixels are arranged in a line is provided, and the display array is moved relative to an observer in a width direction, and image data to be displayed is sequentially ordered by a predetermined amount. A display control means for supplying light to the display array at a speed corresponding to the speed of the movement and driving the light emission of the display array, an image of the display array is scanned two-dimensionally on the retina of an observer, and an image lag effect is generated. In a scanning display device in which an image of a plane is made visible, the display array includes a plurality of display element rows arranged at predetermined intervals in the direction of movement, and the display control unit includes It is configured to sequentially supply image data with a delay corresponding to the speed of the movement and a time corresponding to the interval between the respective display element rows, in the order of the movement direction for each of the plurality of display element rows, Scan type display device in which a plurality of display images by the scanning of the display element array shown the array is characterized in that substantially overlap in agreement. 2. Each of the display pixels in the display array is a multicolor display element in which a plurality of LED chips having different emission colors are mounted on one small lens body, and the image data drives the LED chips for each color. 2. The scanning type display device according to claim 1, wherein the scanning type display device comprises color-specific data. 3. A plurality of display element rows in the display array, wherein a plurality of lens-equipped LEDs having different emission colors are arranged in a plurality of rows for each color. 2. The scanning display device according to claim 1, wherein each color data of one image is sequentially supplied to the LED line with a lens for each color with the time delay.