KR100389021B1 - Driving Method of Plasma Display Panel Using Radio Frequency - Google Patents

Abstract

The present invention relates to a method of driving a high frequency plasma display panel which can improve contrast and lower address voltage.

The driving method of the high frequency plasma display panel of the present invention includes performing a reset discharge for initializing a discharge cell and a priming discharge for lowering an address discharge voltage in a reset period.

Description

Driving Method of Plasma Display Panel Using Radio Frequency

The present invention relates to a method of driving a high frequency plasma display panel, and more particularly, to a method of driving a high frequency plasma display panel which improves contrast and lowers an address voltage.

Plasma Display Panels (hereinafter referred to as "PDPs") display an image including characters or graphics by emitting phosphors by 147 nm ultraviolet rays generated upon discharge of He + Xe or Ne + Xe gas. Such a PDP is not only thin and easy to enlarge, but also greatly improved in quality due to recent technology development. These PDPs are largely classified into a DC drive method and an AC drive method.

The AC drive PDP has the advantages of low voltage driving and long life compared to the DC drive method, and thus will be spotlighted as a display device in the future. In addition, the AC drive type PDP displays an image by causing an AC voltage signal to be applied between electrodes arranged with a dielectric interposed therebetween so that discharge occurs every half cycle of the signal. The AC PDP uses a dielectric material in which wall charges are accumulated on the surface during discharge.

Referring to FIG. 1, an AC PDP includes an upper substrate 1 on which a sustain electrode pair 10 is formed, and a lower substrate 2 on which an address electrode 4 is formed. The upper substrate 1 and the lower substrate 2 are spaced in parallel with the partition 3 therebetween. A mixed gas such as Ne-Xe, He-Xe, or the like is injected into the discharge space provided by the upper substrate 1, the lower substrate 2, and the partition wall 3. The pair of sustain electrodes 10 are paired in two in one plasma discharge cell. Any one of the sustain electrode pairs 10 causes an opposite discharge to the address electrode 4 in response to the scan pulse supplied in the address period, and performs surface discharge with the adjacent sustain electrode 10 in response to the sustain pulse supplied in the sustain period. It is used as a scanning / sustaining electrode. In addition, the sustain electrode 10 adjacent to the sustain electrode 10 used as the scan / sustain electrode is used as a common sustain electrode to which a sustain pulse is commonly supplied. The dielectric layer 8 and the passivation layer 9 are stacked on the upper substrate 1 on which the sustain electrode pairs 10 are formed. The dielectric layer 8 serves to limit the plasma discharge current and to accumulate wall charges during discharge. The protective film 9 prevents damage to the dielectric 8 due to sputtering generated during plasma discharge and increases the emission efficiency of secondary electrons. This protective film 9 is usually made of magnesium oxide (MgO). The lower dielectric layer 6 is formed on the lower substrate 2 to cover the address electrode 4, and the partitions 3 for dividing the discharge space extend vertically. On the surfaces of the lower substrate 2 and the partitions 3, a fluorescent layer 5 which is excited by vacuum ultraviolet rays and generates visible light is formed.

In such an AC-type PDP, one frame is composed of a plurality of subfields, and gradation is realized by a combination of subfields. For example, in the case where 256 gray levels are to be realized, one frame period is time-divided into eight subfields. In addition, each of the eight subfields is divided into a reset period, an address period, and a sustain period. The full screen is initialized during the reset period. In the address period, cells in which data is to be displayed are selected by writing discharge. The selected cells are discharged in the sustain period. The sustain period is lengthened by 2 ⁿ periods according to the weight of each of the subfields. In other words, the sustain period included in each of the first to eighth subfields is lengthened by a ratio of 2 ⁰ , 2 ¹ , 2 ² , 2 ³ , 2 ⁴ , 2 ⁵ , 2 ⁶ , 2 ⁷ . For this purpose, the number of sustain pulses generated in the sustain period is increased to 2 ⁰ , 2 ¹ , 2 ² , 2 ³ , 2 ⁴ , 2 ⁵ , 2 ⁶ , 2 ⁷ . The combination of these subfields determines the luminance and chromaticity of the display image.

In such an AC-type PDP, the sustain electrode pair 10 is alternately supplied with a sustain pulse having a duty ratio of 1, a frequency of 200 to 300 kHz, and a pulse width of about 10 to 20 kHz. The sustain discharge occurring between the sustain electrode pairs 10 in response to the sustain pulse occurs only once in a very short moment. The charged particles generated by the sustain discharges move along the discharge path between the sustain electrode pairs 10 according to the polarity of the sustain electrode pairs 10 and accumulate in the upper dielectric layer 8 to remain as wall charges. This wall charge lowers the driving voltage during the next sustain discharge, but reduces the electric field of the discharge space during the sustain discharge. Accordingly, when the wall charge is formed during the sustain discharge, the discharge is stopped. As such, the sustain discharge occurs only once at a very short moment compared to the width of the sustain pulse, and most of the other time is consumed as a preparatory step for wall charge formation and next oil fat discharge. For this reason, in the conventional PDP, since the actual discharge period becomes very short compared to the electric field discharge period, the luminance and discharge efficiency are inevitably low.

In order to solve the problem of low luminance and discharge efficiency of the AC PDP, a high frequency driving PDP (hereinafter referred to as "RFPDP") has been proposed, which generates sustain discharge using high frequency signals of tens to hundreds of MHz. In RFPDP, electrons vibrate in a cell by high frequency discharge.

Referring to FIG. 2, the RFPDP includes a lower substrate 12 having the address electrode 14 and the scan electrode 18 orthogonal to each other, and an upper substrate 30 having the high frequency electrode 28 parallel to the scan electrode 18. ). A first lower dielectric layer 16 is formed between the address electrode 14 and the scan electrode 18 to insulate the electrodes. The second lower dielectric layer 20 and the passivation layer 22 are stacked on the scan electrode 18. A lattice-shaped partition wall 24 is formed on the passivation layer 22. The phosphor 26 is coated on the surface of the lattice partition 24. The upper dielectric layer 29 is formed flat on the upper substrate 30 on which the high frequency electrode 28 is formed.

The RFPDP displays an image as a combination of a plurality of subfields including a reset period, a priming period, an address period, and a sustain period as shown in FIG. In the reset period, the reset pulse RS is supplied to the scan electrode 18 to initialize the discharge cell of the full screen. In the priming period, the priming pulse P is supplied to the address electrode 14 to lower the address discharge voltage, thereby forming wall charges in the discharge cells of the full screen. The priming pulse P may be supplied to the scan electrode 18. On the other hand, when wall charges are formed in the discharge cells, the voltage level of the data pulse D supplied to the address electrode 14 in the address period can be lowered. In the address period, the scan pulse S is sequentially supplied to the scan electrode 18, and the data pulse D synchronized with the scan pulse S is supplied to the address electrode 14. At this time, an address discharge occurs in the discharge cell supplied with the data pulse D, and wall charges are formed on the surface of the second lower dielectric layer 20 by the address discharge. In the sustain period, the trigger pulse T is supplied to the scan electrode 18 and the address electrode 14 for a predetermined period. When the trigger pulse T is supplied to the scan electrode 18 and the address electrode 14, wall charges formed on the surface of the second lower dielectric layer 20 of the discharge cell selected in the address period are activated as space charges. In addition, trigger discharge is generated between the scan electrode 18 and the address electrode 14 to generate space charge. Such space charges vibrate in the discharge space according to the polarity of the high frequency signal R supplied to the high frequency electrode 28. The discharge gas is continuously ionized by the vibrating motion of the electrons. The vacuum ultraviolet rays generated by this discharge excite the phosphor 26 and generate visible light as the phosphor 26 transitions. In this way, RFPDP generates a discharge continuously during a sustain period by using a high frequency signal, thereby increasing luminance and discharge efficiency as compared with an AC PDP.

However, in the conventional driving method of the RFPDP, the discharge accompanied with light emission is generated by the reset pulse RS supplied in the reset period and the priming pulse P supplied in the priming period. As such, discharges involving light emission occur during an undesired period, which causes a problem that the contrast of the RFPDP is lowered. In addition, the priming period may be omitted to improve such a problem. However, if the priming period is omitted, since sufficient wall charges are not formed in the discharge cells, a data pulse D having a high voltage level must be supplied in the address period. In addition, although one priming discharge is generated by the priming pulse P supplied in the priming period, one priming discharge does not form sufficient wall charges and uniform wall charges cannot be formed in all discharge cells. .

Accordingly, an object of the present invention is to provide a method of driving a high frequency plasma display panel which can improve contrast and lower address voltage.

1 is a perspective view showing a conventional three-electrode AC surface discharge type plasma display panel.

2 is a perspective view showing a conventional high frequency plasma display panel.

FIG. 3 is a waveform diagram illustrating driving waveforms of the high frequency plasma display panel of FIG. 2.

4 is a waveform diagram showing a driving waveform of the high frequency plasma display panel according to the embodiment of the present invention;

<Description of Symbols for Main Parts of Drawings>

1,30: upper substrate 2,12: lower substrate

3, 24: partition 4: address electrode

5,26 fluorescent layer 6,8,16,20,29 dielectric layer

9,22: protective film 10: sustain electrode pair

14: address electrode 18: scan electrode

28: high frequency electrode

In order to achieve the above object, the driving method of the high frequency plasma display panel according to the present invention includes performing a reset discharge for initializing a discharge cell and a priming discharge for lowering an address discharge voltage in a reset period.

Other objects and features of the present invention in addition to the above objects will become apparent from the description of the embodiments with reference to the accompanying drawings.

Hereinafter, a preferred embodiment of the present invention will be described with reference to FIG. 4.

4 is a diagram illustrating driving waveforms applied to a high frequency plasma display panel according to an exemplary embodiment of the present invention.

Referring to Fig. 4, the RFPDP according to the present invention displays an image in a combination of a plurality of subfields including a reset period, an address period, and a sustain period. In the reset period, the reset pulse RS is supplied to the scan electrode to initialize the full discharge cell and to form uniform wall charge in the discharge cell. The lamp waveform is supplied as such a reset pulse. The ramp waveform has a predetermined slope and its voltage level gradually increases. When such a ramp waveform is applied to the scan electrode, a plurality of micro discharges that do not accompany light emission occur. That is, since a large number of micro discharges that do not accompany light emission is generated in the discharge cells, contrast can be improved. In addition, when a plurality of micro discharges are generated in the discharge cells, uniform wall charges are sufficiently formed in the discharge cells. In the address period, scan pulses S are sequentially supplied to the scan electrodes, and data pulses D synchronized with the scan pulses S are supplied to the address electrodes. At this time, an address discharge occurs in the discharge cell supplied with the data pulse D, and wall charges are formed on the surface of the discharge cell by this address discharge. On the other hand, since sufficient wall charges are formed in the discharge cells, the data pulses D having a low voltage level can be supplied to the address electrodes. In the sustain period, a trigger pulse is supplied to the scan electrode and the address electrode for a predetermined period. When a trigger pulse is applied to the scan electrode and the address electrode, the wall charges formed on the surface of the selected discharge cell in the address period are activated as space charges. In addition, trigger discharge is generated between the scan electrode and the address electrode to generate space charge. Such space charges vibrate in the discharge space according to the polarity of the high frequency signal R supplied to the high frequency electrode. The discharge gas is continuously ionized by the vibrating motion of the electrons. The vacuum ultraviolet rays generated by this discharge excite the phosphor, and the visible light is generated as the phosphor transitions.

As described above, according to the driving method of the high frequency plasma display panel according to the present invention, a ramp waveform capable of simultaneously performing a reset discharge and a priming discharge is provided in a reset period. When such a ramp waveform is supplied, a large number of fine discharges are generated in the discharge cells, which do not accompany the discharge, thereby sufficiently forming uniform wall charges in the discharge cells. That is, fine discharge that does not involve discharge occurs in the reset period, so that the contrast can be improved. In addition, since sufficient wall charges are formed in the discharge cells, the voltage level of the data pulse applied to the address electrode can be lowered.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

Claims (2)

In a driving method of a high frequency plasma display panel which is divided into a reset period, an address period, and a sustain period, and generates a sustain discharge by supplying a high frequency to the high frequency electrode during the sustain period. And simultaneously performing a reset discharge for initializing a discharge cell and a priming discharge for lowering an address discharge voltage in the reset period. The method of claim 1, And supplying a ramp waveform to a scan electrode formed on the lower electrode of the discharge cell during the reset period.