KR100426574B1 - Method for driving ac pdp using local scanning method - Google Patents

Abstract

PURPOSE: A method for driving an AC PDP using a local scanning method is provided to improve the scanning efficiency by diving a screen into eight sections and arranging bit couples in each section according to a proper order. CONSTITUTION: A three-electrode surface discharge AC PDP includes a plurality of cells. Each cell includes two row electrodes and one column electrode. A screen of the three-electrode surface discharge AC PDP is divided into eight sections of B1, B2, B3, B4, B5, B6, B7, and B8. Top bits and bottom bits of digital image signals are formed as eight couples of (l8,l1), (l7,l2), (l6,l3), (l5,l4), (l4,l5), (l3,l6), (l2,l7), and (l1,l8). The bits and bottom bits of digital image signals are arranged and scanned in each section according to a proper order by performing four steps. An erasing pulse is applied to a scan electrode after a predetermined period.

Description

AC PDP Driving Method Using Block Scan Method

1 is a structure of a three-electrode surface discharge AC PDP cell

2 is a layout view of a conventional electrode of a 3 low-pole surface discharge AC PDP.

3 shows a conventional subfield scanning method for implementing 256 gray levels.

Figure 4 is a first step of the zonal scanning scheme for 256 gray level implementation

Figure 5 shows two stages of zonal scanning for 256 gray level implementation.

Figure 6 shows three stages of zonal scanning for 256 gray level implementation.

7 shows four steps of a zonal scanning scheme for 256 gray level implementation.

* Explanation of symbols for main parts of the drawings

1: lower insulation plate 2: upper insulation plate

3: row electrode 4: column electrode

5: lower insulating film 6: upper insulating film

7: protective film 8: discharge space

9 fluorescent film 10 partition wall

11: cell 12: vacuum sealing area

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a driving method of a plasma display panel (PDP), which is one of the flat panel displays, and collects bits of the same type from the MSB to the LSB of a digital video signal, and then places higher bits. The present invention relates to a method of forming an entire screen by sequentially scanning each pair of video signals in an equally divided region of one screen by forming one bud and one lower bit. This area scanning method can enjoy the reduced time required for screen scanning compared to the conventional subfield driving method, which can increase the brightness of the AC PDP image, and the right bit and the short discharge time which require long discharge time By driving the required lower bits in pairs, it is possible to reduce the flicker phenomenon caused by the difference in uneven discharge time.

The plasma display device (PDP) is discharged through the voltage control applied between the vertical and horizontal electrodes of the cells constituting the pixel, the amount of discharged light is adjusted by varying the length of the discharge time in the cell. The full screen includes a light pulse for inputting a digital image signal to the vertical and horizontal electrodes of each cell, a scan pulse for scanning, a sustain pulse for maintaining a discharge, and a discharged cell. It is obtained by driving a matrix type by applying an erase pulse for stopping the discharging. The level of brightness (adjustment, gray level) required for the image display is determined by varying the length of time each cell is discharged within a given time (1/30 second for NTSC TV signals) required to display the entire image. Implement At this time, the brightness of the screen is determined by the erection when each cell is driven to the maximum, and in order to increase the latitude, the driving circuit can maintain the discharge time of the cell as long as possible within the given time to compose one screen. Should be designed. Contrast, which is the difference in contrast, is determined by the brightness and luminance of the background of the lamp, and in order to increase the contrast, not only the background should be dark, but also the brightness needs to be increased.

For flat panel displays for HDTV, 256 gray levels are required, the resolution must be at least 1280 x 1024 and the contrast under 200 lux is required at least 100: l. Therefore, an image digital signal necessary for 256-contrast image display requires an 8-bit signal for each of RGB, and a cell discharge time must be kept as long as possible in order to obtain required luminance and contrast. Gray level implementations include a line scanning method and a sub picture method. Among the AC PDPs, the most noticeable method is the sub picture method.

The subfield method collects 8-bit digital video signals from the MSB to LSB with the same weight bits, and then the MSB is in time T, and the lower bits are in bit order close to the MSB. Scans for T / 2, T / 4, ... T / 128 to form a sub-screen, and uses 256-level gray levels using the integral effect of the eye on the light emitted from each sub-screen. However, since it must be driven by the PDP matrix method, there is a limitation that a write pulse cannot be applied to one or more horizontal electrodes at a time for a given vertical electrode, and thus the horizontal electrodes must be driven at different times. Therefore, in order to configure each sub-screen, it is necessary to scan all the horizontal electrodes, and each cell can maintain the discharge only for a time reduced by the scanning time from the time allocated to the average sub-plane.

The time required for scanning increases as the number of horizontal electrodes increases, and since the discharge cannot be maintained during this time, it becomes a factor that causes latitude and contrast degradation of the PDP, and thus the time required for scanning needs to be reduced as much as possible. In addition, since the difference in the discharge time between the upper bits and the lower bits when the sub-screen configuration is large and configures the sub-screen immediately, a lot of flicker occurs due to the difference in the discharge time. In order to reduce the flicker phenomenon, it is necessary to configure the upper bit subscreen with long discharge time and the lower bit subscreen with short discharge time in a proper order.

1 illustrates a three-electrode surface discharge AC PDP cell structure which is currently used. The spacer 10 keeps the first insulating substrate 1 and the second insulating substrate 2 in parallel and insulates the cells from each other. They consist of two scan electrodes 3 'and a common electrode 3 "and are arranged parallel to each other on the insulating plate 1. The column electrodes 4 are parallel to each other under the insulating plate 2, respectively. Arranged to form a matrix with the row electrodes 3. The insulating layers 5 and 6 cover the row electrodes 3 and the column electrodes 4, respectively, to cover the electrodes. As the electrode is covered with an insulating film, the discharge disappears immediately when a direct current voltage is applied between the electrodes, and the discharge disappears immediately.In the case of an AC PDP having such an electrode structure, the polarity is continuously reversed to maintain the discharge. AC voltage must be applied between electrodes The protective layer (7) is covered on the insulating film (5), which not only protects the insulating film and extends its life, but also improves the emission efficiency of secondary electrons and discharge characteristics due to the contamination of nitrides in refractory metals. MgO thin film is mainly used to reduce the change of Fluorescent Layer (9) is applied on the insulating layer (6), and is excited by ultraviolet rays generated by the discharge to red, green, and color (RGB) Visible light generation The discharge space 8 is a space of a cell in which a discharge proceeds, and is mainly filled with a mixture of Ar and Xe to improve ultraviolet emission efficiency.

2 shows the electrode arrangement of the conventional three-electrode surface discharge AC PDP. Each cell 11 is formed at a point where the row electrodes and the column electrodes cross at right angles to each other, and the row electrodes maintain a discharge with a scan (S ₁ -S _m ) electrode group mainly used for scanning of the screen. It consists of a group of common (C ₁ -C _m ) electrodes, which are used mainly for giving, and column electrodes are mainly used for data input. The sealing region 12 is used to maintain the vacuum of the entire PDP, and an insulator spacer is formed between the insulating layers 1 and 2, and the sealing region is sealed using a sealing agent.

Pulse application to each electrode is as follows. Sustain pulses are applied to the common (C ₁ -C _m ) electrodes to maintain the discharge of the cell, and the scan (S ₁ -S _m ) electrodes have the same shape as the pulses of the common electrodes, but the position is different. Another sustain pulse is applied. In addition, scan pulses used to scan the screen and erase pulses for stopping the discharge of the discharged cells are additionally input to each of the scan electrodes to control the cell on and off. Write pulses are input to the column electrodes D ₁ to D _n by inputting data pulses synchronized with scan pulses input to the scan electrodes. If the cells S ₁ and D _l are to be discharged, the voltage between the Sl electrode and the Dl electrode is discharged when the data pulse, which is a positive probe, is inputted to D ₁ and the scanning pulse is inputted to S1 in synchronization with the data pulse. The discharge occurs because the voltage exceeds the threshold voltage necessary to cause the discharge. This state is maintained until the next erasing pulse is applied by the electric field generated by the charged particles charged to the insulating film by the discharge and the electric field generated by the sustain pulses of S ₁ and C ₁ . When the erase pulse is applied, a small discharge is generated that is insufficient for the sum of the electric field caused by the dust particles and the electric field caused by the erase pulse to sustain the discharge, and the discharge disappears when the next sustain pulse is applied. To summarize the roles of the electrodes described above, scan electrodes serve as sustain and screen scan, while common electrodes perform only a sustain function. The data electrodes are responsible for data input for screen configuration.

3 shows a scanning method of a conventional sub-screen driving method for implementing 256 gray levels. One field consists of eight subscreens, and each subscreen time is constant T _A. Therefore, the time required to compose one screen becomes T _FIELD 8T _A. The time used for discharging among the time T _A allocated to each subscreen is T _A , T _A / 2, T _A / 4, T _A / 8, T _A / 16, T _A / 32, Only used during T _A / 64 and T _A / 128. Accordingly, one field time 8T _A time which can be used for the discharge of (referred to as the total sustain period thereafter and sign uses T _S. The 2T _A and the use time can not be used for the discharge T _NS.) Is a 6T _A. Therefore, the percentage of waste time T _NS and the efficiency are as follows.

These figures show that in case of AC PDP using the sub picture driving method, the actual time that can be used for discharge is less than 25% of the total time, and it acts as the main factor that drastically reduces the luminance in the AC PDP using the sub picture driving method. do.

In the present invention, in order to increase the time used for discharging, the digital video signal is collected from the same type of bits from the MSB to the LSB, and then the upper and lower bits are paired, and one screen is equalized in the horizontal direction. The present invention relates to a method for constituting an entire screen by sequentially scanning video signals composed of each pair in a divided region. This area scanning method can reduce the time required for screen scanning compared to the conventional subfield driving method, which can increase the brightness of the AC PDP image, and requires a soy bit that requires a long discharge time and a short discharge time. By driving the lower bits in pairs, it is possible to reduce the flicker phenomenon caused by the difference in uneven discharge time.

The zone scan method uses the upper and lower bits (I ₈ , I ₁ ), (I _7, I ₂ ), (I ₆ , I ₃ ), (I ₅ , I ₄ ), (I ₄ , I ₅ ), respectively. _{, (I 3, I 2)} , (I 2, I 7), (I 1, I 8) , create a bit pair in the sequence, even if the 8-Up screen as given in 4 from the upper B _1, B ₂ By setting the zones indicated by, B ₃ , B ₄ , B ₅ , B ₆ , B ₇ , B ₈ , the pairs of bits are scanned in four steps in the proper order to form the entire screen. The first stage scan places the bit pairs in the order (I ₈ , I ₁ ) to (I _1, I ₈ ) in each zone, as shown in FIG. 4. Scanning of the screen _first scans I ₈ bits, which are the preceding bits of the (I ₈ , I1) bit pair in the B ₁ region, in the order from the upper electrode to the lower electrode, then I ₇ bits in the B ₂ region, and I in the B ₃ region. ₆ bits, and B ₄ is sequentially scanned in a zone up to the order of I ₁ to B _8-bit section, such as I ₅ bits. Thereafter, the I ₈ bits are scanned in the order of the lower electrode to the upper electrode in the lowermost region B ₈ to scan the trailing bits of the bit pair. That is, the addition zone is injected in order to I ₇ bits, B _6, the zone I ₆ I _1-bit accept the order of bits in the section B _1. The erase pulse is applied to the scan electrodes after a predetermined time allocated for each bit. In the following steps, the erase pulse is applied in the same manner.

In the second step scan, the bit pairs are rotated one step downward and the lower four areas one step upward from the first step scan (I ₅ , I ₄ ) to (I ₄ , I as shown in FIG. 5. ₅ ) Place them in order. Scanning of the screen is I ₅ to I _6, B ₈ zone to I _7, B ₅ zones to I _8, B ₆ zone B ₇ zones for for the preceding bit scanning in the same order as in Step 1, and the succeeding bit , I ₄ in B ₁ , I ₃ in B ₄ , I ₂ in B ₃ and I ₁ in B ₂ . At this time, after injection of I ₅ bits to B ₈ zone it can be seen that no scanning is not made for I to scan the _four I T _A / 8 hours in B ₁ zone, which is injected with I ₁ bits in B ₇ Area In order to scan I ₄ bits in the B ₈ zone and I ₈ bits in the zone again, it takes T _A / 8 more time than the minimum time given in Fig. 4 to keep the MSB time constant. In order to do this, a dose of T _A / 8 should be added after the lower 4 zones have been injected.

Figure 6 illustrates the placement and scanning order of the third stage bit pairs. In the third stage scan, the bit pairs are rotated one more step downward in the upper four zones and one more step upward in the lower four zones. Scanning of the screen is I ₅ to I _6, B ₇ zone to I _7, B ₈ zone I _8, B ₅ zone B ₆ area for the order of scanning and the succeeding bit, such as Step 1 for the sinhaeng bit , is scanned by I ₁ bit in order to I _4, I _3, B ₄ to zone I _3, B ₄ B ₁ to the section B ₂ to the section area. At this time, after injection of I ₅ bits in B ₇ zone can be seen that no scanning is not made while I ₄ I T _A / to scan for 4 hours in the B ₁ zone, which is injected with I ₁ bits in B ₆ zone Then, after scanning I ₁ bit in the B ₈ zone and then injecting I ₈ bit in this zone again, it takes T _A / 4 more time than the minimum time given in Fig. 4 to schedule the MSB time. In order to maintain this, a time of T _A / 4 must be added after the lower 4 zones have been injected.

Figure 7 shows the placement and scanning order of the fourth stage bit pairs. In the fourth stage scan, the bit pairs are rotated one more step downward in the upper four zones and one more step upward in the lower four zones. Scanning of the screen is I ₅ to I _6, B ₆ zone to I _7, B ₇ area is I _8, B ₈ zone B ₅ zones for for the preceding bit scanning in the same order as l stages, and the succeeding bit , is scanned by ₄ I, B ₂ zone _{I 3, I 2, B 4} I 1 -bit order in the section B ₂ to the section B ₃ zone. At this time, after injection of I ₅ bits to B ₆ zone so the scan for I to scan the _four former 3T _A / 8 hours in the B ₁ section not occur, and this to the reasons discussed earlier to maintain a constant time of MSB This is because 3T _A / 4 of time must be added after the lower 4 zones have been injected.

If all the 4th step scans are bureaucratic in the above order, as shown in the table below, all 8 I ₁ .I _{2. To} I ₇ .I ₈ bits are processed in the whole area, so the configuration of one screen is bureaucratic.

This section scan method takes the time required to scan the screen.

The total sustain time T _{S at} which the discharge can proceed is shown in FIG.

T _S = 4T _A

The efficiency and the percentage of time wasted T _NS are given by

That is, compared with the conventional sub-screen scanning method having an efficiency of 25%, an efficiency about 1.8 times increased can be obtained.

In the zone scanning method described above, the screen is divided into eight zones and bit pairs are placed in each zone in the proper order to scan in a given order, so that the efficiency can be increased by 1.8 times compared to the conventional sub-screen scanning method. By scanning the long MSBs and the short LSBs alternately with each other, the flicker of the screen can be reduced. The method can be applied in the same way to not only three-electrode AC PDPs but also other types of PDPs.

Claims (5)

In a three-electrode surface-discharge AC PDP, in which each cell consists of two row electrodes and one column electrode, the screen is moved from the top to B ₁ , B ₂ , B ₃ , B ₄ B ₅ , B ₆ , B ₇ , B ₈ Divide into 8 zones marked with (I ₈ , I ₁ ), (I ₇ , I ₂ ), (I ₆ , I ₃ ), (I ₅ , I ₄ ), ( 8 pairs in the order of I ₄ , I ₅ ), (I ₃ , I ₂ ), (I ₂ , I ₇ ), (I ₁ , I ₈ ), and place them in each zone in the appropriate order over four steps. Scanning in a given order, and the erase pulse is applied to the scan electrodes after a predetermined time for each bit has passed. The method of claim 1, wherein the first stage injection is performed in the B ₁ region (I ₈ , I ₁ ), in the B ₂ region (I ₇ , I ₂ ), and in the region (I ₆ , I ₃ ), B as shown in FIG. 4. _In zone ₄ (I ₅ , I ₄ ) in zone B ₅ (I ₄ , I ₅ ), in zone B ₆ (I ₃ , I ₂ ), in zone B ₇ (I ₂ , I ₇ ), in zone B ₈ Bits are arranged in the order (I ₁ , I ₈ ), and scanning of the screen _first looks at the I ₈ bits, which are the preceding bits of the B ₁ region, in the order of the upper electrodes from the lower electrodes, and then sequentially, B ₂ , B _3. ..... sequentially scans the preceding bits of the B ₈ zones, and the trailing beetles of the bit pair scan the I ₈ bits from the lower electrode to the upper electrode in the lower zone B ₈ after the completion of the scanning of the preceding beetle. Then, the driving method of sequentially scanning the trailing bits of B ₇ , B ₆ , ..... B ₁ zones in the same manner. The second stage injection is in zone B ₁ (I ₅ , I ₄ ), in zone B ₂ (I ₈ , I ₁ ), in zone B3 (I ₇ , I ₂ ), and zone B ₄ , as given in FIG. 5. In (I ₆ , I ₃ ), in Zone B ₅ (I ₃ , I ₆ ), in Zone B ₆ (I ₂ , I ₇ ), in Zone B ₇ (I ₁ , I ₈ ), in Zone B ₈ ( I ₄ , I ₅ ) are arranged in the order of bits, and scanning of the screen _first scans I ₅ bits, which are the preceding bits of the B ₁ zone, in the order of the upper electrode to the lower electrode, and then B ₂ , B ₃ ... . After scanning the preceding bits of the B ₈ zones sequentially, the trailing bits of the bit pair scan the I ₈ bits from the lower electrode to the upper electrode in the lower region B ₇ after the scanning of the preceding bit is completed. In the same way, scan the trailing bits in the order of B ₆ , B ₅ , B ₈ , delay by one eighth of the sub picture time T _A , and then order the trailing bits in the order of B ₁ , B ₄ , B ₃ , and B ₂ . A driving method for scanning sequentially. The third stage injection is given in section B ₁ (I ₆ , I ₃ ), in section B ₂ (I ₅ , I ₄ ), in section B ₃ (I ₈ , I ₁ ), B ₄ , as given in FIG. 6. In zone (I ₇ , I ₂ ), in zone B ₅ (I ₂ , I ₇ ), in zone N ₆ (I ₁ , I ₈ ), in zone B ₇ (I ₄ , I ₅ ), in zone B ₈ (I ₃ , I ₆ ) The bits are arranged in order, and the scanning of the screen _first looks at the I ₆ bits, which are the preceding bits of the B ₁ region, in the order of the upper electrodes from the lower electrodes, and then sequentially, B ₂ and B _3. ..... sequentially scans the preceding bits of the B ₈ zones, and the trailing bits of the bit pair scan the I ₈ bits of the lower zone B ₆ zone from the lower electrode to the upper electrode after scanning of the preceding bit After that, the trailing bits are scanned in the order of B ₅ , B ₈ , and B ₇ , delayed by 1/4 of the sub picture time T _A , and the trailing bits in the order of B ₂ , B ₁ , B ₄ , and B ₃ . Driving method to scan sequentially. The method of claim 1, wherein the fourth stage of injection is in zone B ₁ (I ₇ , I ₂ ), in zone B ₂ (I ₆ , I ₃ ), in zone B ₃ (I ₅ , as given in FIG. 7). I ₄ ), in zone B ₄ (I ₈ , I ₁ ), in zone B ₅ (I ₁ , I ₈ ), in zone B ₆ (I ₄ , I ₅ ), in zone B ₇ (I ₃ , I ₆ ), the B ₈ zones (I _2, I ₇₎ place the bit image in the sequence, and the scanning of the screen, first consider the order of the lower electrode to the leading bit of I ₇ bits of B ₁ zone from the upper electrode, B ₂ , B ₃ .... Sequentially scan the preceding bits of the B ₈ zones, the trailing bits of the bit pair are the I ₈ bits of the lower zone B ₅ after the scanning of the preceding bit Scan in sequence, then scan the trailing bits in the same order as B ₈ , B ₇ , B ₆ , delay by 3/8 of the sub picture time T _A , and then B ₃ , B ₂ , B ₁ , B ₄ A driving method for sequentially scanning the trailing bits in chronological order.