KR20030080148A - method for random scan of Organic Electroluminescence display device with passive matrix structure - Google Patents

Abstract

PURPOSE: A random scanning method of an organic electro-luminescence display having a structure of passive matrix is provided to remove a flickering phenomenon by using random binary series without increasing frame frequencies. CONSTITUTION: An organic electro-luminescence display having a structure of passive matrix includes a plurality of data lines arrayed to one direction, a plurality of scan lines arrayed perpendicularly to the data lines, and a plurality of pixels formed on intersection areas between the data lines and the scan lines. A random scanning method of the organic electro-luminescence display having the structure of passive matrix includes a random scanning process. The random scanning process is to select randomly a scanning order of the scan lines in order not to scan the scan lines toward the predetermined direction. The random scanning method includes a process for outputting a stored value of the last stage of a shift register(10), a process for shifting the stored values of each stage to the next stages, a process for producing a result of a logical operation for the stored value and the output value by using a logical expression(20), a process for storing the result into the first stage of the shift register(10), and a process for selecting the scan line.

Description

Method for random scan of Organic Electroluminescence display device with passive matrix structure

TECHNICAL FIELD The present invention relates to a flat panel display device, and more particularly, to a random scanning method of an organic EL display device having a passive matrix structure.

Recently, in the field of flat panel display, rapid progress has been made.

In particular, flat-panel displays, which started to emerge as the leading liquid crystal displays (LCDs), have surpassed the Cathode Ray Tube (CRT), which has been the most used in the display field for decades, and recently, the plasma display panel (PDP) and the visual fluorescence (VFD). Many developments are being made such as display (FED), field emission display (FED), light emitting diode (LED), and electroluminescence (EL).

Such display devices are not only good in visibility and color, but also have a simple manufacturing process, thereby expanding their applications in many areas.

In particular, LED arrays are becoming increasingly popular as image sources in direct or virtual displays.

That is, the LED can generate a relatively large amount of light, so that the display of the LED array can be used for various ambient conditions.

Organic LED arrays are also increasing in applicability to small sized products, especially portable electronic products such as pagers, cellular and portable phones.

As such, organic LED arrays can generate enough light for use as displays in a variety of ambient light conditions, from low or low light levels to bright light environments, and can also be manufactured relatively inexpensively, Applications can range from small sizes (less than one inch) to fairly large sizes (tens of inches).

In addition, the LEDs provide a very wide viewing angle.

Recently, the organic EL display panel has been attracting attention as a flat panel display panel with less space occupancy due to the enlargement of the display device.

This organic EL display device is classified into a passive matrix display device and an active matrix display device by a panel structure.

The passive matrix display device has a structure in which an organic EL material is positioned at an intersection point of column lines and row lines.

In such a passive matrix organic EL display device, a phenomenon in which a screen shakes like a wave, that is, a flicker phenomenon, occurs when driving at a constant frame frequency.

In order to eliminate or reduce such flicker, the frame frequency must be increased.

However, as the frame frequency increases, the ratio of delay time due to panel resistance and capacitance in one scan time, that is, the ratio of time that does not contribute to luminance increases.

As described above, the passive matrix organic EL display device becomes lower in luminance as the frame frequency increases, and consumes more power to increase the frame frequency while maintaining the same luminance.

Therefore, another method for eliminating or reducing the flicker phenomenon is to scan in a random order such that the scan order for one frame time is not directional.

However, it is very difficult to implement a hardware-complete complete binary sequence in which the scan order is not directional as well, and the scan IC and the data IC need to drive data in accordance with the order of the scan by the random binary string. I have a problem with sharing information about.

Accordingly, the present invention has been made to solve the above problems, and provides a scanning method of an organic EL display stationary structure having a passive matrix structure that eliminates flicker using a complete random binary sequence without increasing the frame frequency. The purpose is.

1 is a block diagram of a PN sequence generator for a random scan method according to the present invention

2 is a view showing an embodiment of a random scan method using a PN sequence generator according to the present invention

3 is a diagram illustrating an output value and a register value according to each clock in a PN sequence generator for a random scan method according to the present invention;

* Explanation of symbols for main parts of the drawings

10, 30: shift register 20, 40: logic section

A characteristic feature of the random scanning method of the passive matrix organic EL display device according to the present invention for achieving the above object is a plurality of data lines arranged in one direction and a plurality of data lines arranged in a direction perpendicular to the data line. A scanning method in a display apparatus having scan lines and pixels formed at intersections of the data line and the scan line, the scanning method of scanning the plurality of scan lines in a random order without directionality have.

According to another aspect of the present invention, the random order may include outputting a value stored at the last stage of a plurality of connected registers as an output value, moving the values stored at each stage to the right by one stage, and storing the predetermined values among the plurality of registers. Calculating a value stored in the stage and the output value by using a predefined logic expression, feeding back the calculated value to the front end of the register, and a value of a binary sequence currently stored in a plurality of registers. And selecting a scan line corresponding to the scan line.

Another feature of the present invention is that each of the above steps is performed in succession one cycle of {2} ^ {n} -1 (n is the number of registers) for each clock.

Other objects, features and advantages of the present invention will become apparent from the following detailed description of embodiments taken in conjunction with the accompanying drawings.

A preferred embodiment of the random scanning method of the passive matrix organic EL display device according to the present invention will be described with reference to the accompanying drawings.

1 is a diagram illustrating a configuration of a PN sequence generator for a random scan method according to the present invention.

Referring to Fig. 1, a shift register 10 composed of a plurality of registers, an output value of the last stage of the shift register and a value stored in another predetermined register are calculated by a defined logical expression, and the calculated value is calculated by the register. It consists of a logic unit 20 that feeds back to the first stage.

Referring to this operation, the value stored in the last stage of the shift register 10 in one clock unit is output as an output value, and the values stored in each stage are shifted to the right by one stage and stored.

Subsequently, in the register at the front end, the output value and the value stored in a predetermined stage among the plurality of registers are calculated by a logic expression defined in the logic unit 20, and the calculated value is fed back and stored.

Using the PNudo-Noise Sequences generator, if only the initial value of each stage is known, a simple hardware predictable and random binary sequence can be obtained.

If the driving order of the scan lines is determined according to the binary string, the driving order of the scan lines without direction can be obtained, thereby eliminating or reducing the flicker phenomenon.

At this time, the PN sequence generator After -1 (n is the number of shift registers), it returns to the initial set value. Therefore, the problem of increasing the number of scan lines to be driven can be easily solved by increasing the number of shift registers 10.

In addition, if the data IC and the scan IC share information on the singular, logical, and initial values of the binary sequence generator, the display can be easily driven.

2 is a diagram illustrating an embodiment of a random scan method using a PN sequence generator according to the present invention.

Referring to Fig. 2, a shift register 30 composed of four registers, an output value of four stages and a stored value of three stages of the shift register are calculated by XOR, and the calculated value is fed back to the first stage of the register. It consists of a logic unit 40 to.

In this case, since the number of stages of the shift register is four, the number of scan lines that can be driven by the shift register is By -1, 15 scan lines can be driven.

The operation of the PN sequence generator configured as described above will be described in detail with reference to the accompanying drawings.

3 is a diagram illustrating an output value and a register value according to each clock in the PN sequence generator for the random scan method according to the present invention.

First, the shift register 30 has four stages, and an initial value is defined as "1001".

During the first clock, "1", which is the value of the four stages of the shift register 30, is output. Then, the output value "1" and "1", which is a value obtained by XORing the value "0" of the third stage, are fed back and stored in the first stage of the shift register 30.

In addition, the value "1" of the first stage is moved to two stages, the value "0" of the two stages is moved to three stages, and the value "0" of the three stages is moved to four stages, and is stored.

Thus, when the first clock is completed, the shift register 30 has a value of "1100".

Next, during the second clock, the output is " 0 " which is a value of the four stages of the shift register 30. Then, the output value "0" and "0", which is a value obtained by XORing the value "0" of the third stage, are fed back and stored in the first stage of the shift register 30.

Further, the value "1" of one stage is moved to two stages, the value "1" of two stages is moved to three stages, and the value "0" of three stages is moved and stored to four stages.

Thus, when the second clock is completed, the shift register 30 has a value of "0110".

Next, during the third clock, the output is " 0 " which is a value of the four stages of the shift register 30. Then, the output value " 0 " and " 1 " which is the value obtained by XORing the value " 1 " of the third stage are fed back and stored in the first stage of the shift register 30. FIG.

Further, the value "0" of one stage is moved to two stages, the value "1" of two stages is moved to three stages, and the value "1" of three stages is moved and stored to four stages.

Thus, when the third clock is completed, the shift register 30 has a value of "1011".

When the fifteenth clock is completed in this manner, the shift register 30 returns to the initial defined "1001" from the sixteenth clock.

Then, the process is repeated in the same order as above.

As described above, when the value stored in the shift register for each clock is expressed in decimal, values from 1 to 15 are randomly calculated.

Therefore, when the scan order of the driven scan line is set using the calculated value, the set scan order is performed in a random order every time so as not to have a direction.

The random scanning method of the passive matrix organic EL display device according to the present invention as described above has the following effects.

First, the flicker phenomenon can be eliminated or reduced without increasing the frame frequency.

Second, the increase in the number of scan lines can be solved by simply increasing the number of shift registers.

Third, if the data IC and the scan IC share information about the singular, logical, and initial values of the binary sequence generator, the driving of the display can be easily driven.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments, but should be defined by the claims.

Claims (3)

In a display device having a plurality of data lines arranged in one direction, a plurality of scan lines arranged in a direction perpendicular to the data line, and pixels formed in the intersection of the data line and the scan line In the scanning method, And a scanning method of scanning the plurality of scan lines in a random order without directionality. The method of claim 1, wherein the random order Outputting the values stored in the last stage of the register connected to a plurality as output values, and moving the values stored in each stage to the right by one stage and storing them; Calculating a value stored in a predetermined stage of the plurality of registers and the output value by a predefined logical expression; Feeding back the calculated value and storing the calculated value at the front end of the register; And selecting a scan line corresponding to a value of a binary sequence currently stored in a plurality of registers as a scan line. The method of claim 2, Wherein each of the steps is performed for each clock in succession one cycle of {2} ^ {n} -1 (n is the number of registers) in one cycle.