KR100312505B1 - Apparatus for Driving Plasma Display Panel Driving with Radio Frequency Signal and Method Thereof - Google Patents

Abstract

The present invention relates to a driving apparatus of a high frequency plasma display panel and a driving method thereof so that high frequency power can be efficiently supplied to a high frequency electrode.

A driving apparatus of a high frequency plasma display panel according to the present invention includes a display panel discharged by a high frequency signal; A high frequency generator for generating a high frequency signal; An impedance matching unit connected to the high frequency electrode input terminal for impedance matching of the display panel; A first switch connected between the high frequency generator and the impedance matching unit to switch the high frequency signal to be supplied to the high frequency electrode; Impedance correction means connected to the first switch, the high frequency generator and the display panel to compensate for the lower input impedance value of the high frequency electrode input terminal to which the high frequency signal is supplied when the sustain discharge is on than the off state.

Accordingly, the input impedance seen from the input terminal of the high frequency electrode is constantly maintained regardless of the on / off state of the sustain discharge, so that the high frequency power is efficiently supplied to the high frequency electrode when the sustain discharge is turned on.

Description

Apparatus for Driving Plasma Display Panel Driving with Radio Frequency Signal and Method Thereof}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a driving apparatus for a high frequency plasma display panel and a driving method thereof, and more particularly, to a driving apparatus for a high frequency plasma display panel and a method for driving the same.

Plasma Display Panel (hereinafter referred to as 'PDP') is a display device using visible light generated from a phosphor when ultraviolet rays generated by gas discharge excite the phosphor. PDP is thinner and lighter than Cathode Ray Tube (CRT), which has been the mainstay of display means, and it has the advantage of being able to realize high-definition large screen and having a wide viewing angle. The PDP is composed of discharge cells arranged in a matrix. In the PDP, by adjusting the number of sustain discharges generated in each discharge cell, stepwise brightness, ie, gray scale, required for image display is realized. In the actual AC drive type PDP, in order to perform sustain discharge, a rectangular pulse of 200 mW to 300 mW is periodically applied to the discharge sustaining electrode periodically. In AC-driven PDP, the discharge occurs only once at a very short time for one spherical pulse, and most of the discharge time is consumed as a step of forming wall charge and preparing for the next discharge, thereby lowering the discharge efficiency. In order to solve this problem, a PDP (hereinafter referred to as an RF PDP) in which a discharge is caused by a high frequency has been proposed. In the RF PDP, electrons vibrating by the high frequency signal continuously ionize the discharge gas in the discharge region, so that discharge is continuously performed for most of the discharge time.

1 is a perspective view schematically illustrating a discharge cell structure of an RF PDP. Referring to FIG. 1, each discharge cell of an RF PDP includes a data electrode 22 formed on a lower substrate 20 and a lower substrate 20. And a dielectric layer 24 formed on the data electrode 22, a scan electrode 26 formed on the dielectric layer 24 so as to be orthogonal to the data electrode 22, and vertically formed on the dielectric layer 24. A high frequency formed on the back surface of the upper substrate 32 in a direction parallel to the scan electrode 26 with a predetermined space therebetween, the partition wall 28 separating the cells, the phosphor 30 coated on the inner wall of the partition wall 28, and having a predetermined space therebetween. The discharge region 36 is formed to be surrounded by the electrode 34, the upper substrate 32, the lower substrate 20, and the partition wall 28.

When the data pulse is supplied to the data electrode 22 and the scan pulse synchronized with the data pulse is supplied to the scan electrode 26 to select the discharge cell in the PDP, address discharge occurs. At this time, charged particles such as electrons are generated in the discharge region 36, and wall charges are formed in the dielectric layer 24. The formed wall charges lower the discharge voltage during sustain discharge. After the address discharge is performed, a high frequency signal is applied to the high frequency electrode 34 to cause a sustain discharge. The electrons generated in the discharge region 36 vibrate between the high frequency electrode 34 and the scan electrode 26 by a high frequency signal and continuously ionize the discharge gas in the discharge region 36 for almost most of the discharge time. Discharges continuously. As a high frequency signal, a square wave or sinusoidal signal having a frequency of several tens of MHz to several hundred MHz is used. During the sustain discharge period, ultraviolet rays are generated during the transition of the excited gas. The generated ultraviolet rays excite the phosphor 30 formed on the inner wall of the discharge cell, and at this time, visible light is emitted from the phosphor 30 to implement an image of the PDP.

The image gradation of the RF PDP is implemented by an address / display separated subfield (hereinafter referred to as 'ADS') driving method. The ADS driving method is a method of dividing and driving one frame into a plurality of subfields according to the step brightness of the image to be implemented, that is, the gradation. FIG. 2 is a waveform diagram illustrating a driving signal supplied to each electrode of the PDP for each subfield during ADS driving. Referring to FIG. 2, a subfield section for realizing one gray level in the PDP includes the data electrode 22 and the data electrode 22. An AC signal is applied to the scan electrode 26 and divided into an addressing period for performing address discharge, and a high frequency signal is applied to the high frequency electrode 34 for sustain sustain. In the addressing period, a cell to be discharged is selected, and in the sustaining period, the brightness of the selected discharge cell is controlled by adjusting the sustain discharge time. In RF PDP, high frequency sustain discharge occurs only in the sustain period. That is, since the high frequency signal must be applied to the high frequency electrode 34 only in the sustain period, switching for turning on / off the high frequency signal is necessary.

3 is a view showing a conventional driving apparatus for turning on / off a sustain discharge in an RF PDP. Referring to FIG. 3, a driving apparatus for turning on / off a sustain discharge of an RF PDP includes a high frequency generator 60 generating a high frequency signal and an impedance matching unit connected to an input terminal of the high frequency electrode 34 of the PDP 66. And a switch 64 connected between the high frequency generator 60 and the impedance matching unit 62. The switch 64 is switched so that a high frequency signal is applied to the high frequency electrode 34 of the PDP 66 only during the sustain period. The impedance matching unit 62 serves to match the source impedance (hereinafter referred to as 'Z _S ') to the input impedance (hereinafter, referred to as 'Z _IN ') seen from the input terminal of the high frequency electrode 34. Thus, when the switch 64 is turned on, the high frequency power supplied from the high frequency generator 60 is supplied to the PDP 66 without being reflected at the input terminal of the high frequency electrode 34. Meanwhile, in the three-electrode RF PDP shown in FIG. 1, the scan electrode 26 applies an AC pulse in the addressing period to generate an address discharge, and also serves as a ground electrode of the high frequency signal during the sustain period, and is held together with the high frequency electrode 34. Will cause a discharge. Accordingly, in the driving apparatus of the RF PDP, a circuit is configured such that the scan electrode 26 is connected to the ground terminal GND of the high frequency generator 60 during the sustain period as shown in the figure.

In the RF PDP, Z _IN varies depending on whether or not sustain discharge is present in the panel. In detail, the impedance value of the panel itself (hereinafter referred to as 'Z _ON ') when the sustain discharge is occurring is greater than the impedance value of the panel itself (hereinafter referred to as 'Z _OFF ') when the sustain discharge is not occurring. small. When the sustain discharge is occurring, the electrons in the discharge region 36 are in a vibrating motion between the high frequency electrode 34 and the scan electrode 26. Accordingly, the same effect as the gap between the high frequency electrode 34 and the scan electrode 26 becomes narrow during the sustain discharge. Thus, the capacitance value of the panel during sustain discharge (hereinafter referred to as 'C _ON ') is higher than the capacitance value (hereinafter referred to as 'C _OFF ') when sustain discharge is not occurring, and Z _ON becomes smaller than Z _OFF . do. In the conventional case, the impedance matching unit 62 has a circuit designed such that Z _S is matched to Z _ON so that the high frequency power is transmitted to the high frequency electrode 34 at the time of sustain discharge. However, since Z _IN is Z _OFF before the switch 64 is switched from the off state to the on state, impedance matching with Z _S is not achieved. Accordingly, since impedance matching is not performed from the moment when the switch 64 is turned on until sustain discharge occurs in earnest, some high frequency power is reflected from the input terminal of the high frequency electrode 34. Therefore, the conventional driving apparatus has a disadvantage in that the high frequency power is not efficiently supplied to the high frequency electrode when the switch is turned on to cause the sustain discharge.

Accordingly, an object of the present invention is to provide a driving apparatus for a high frequency plasma display panel and a method for driving the same, in which high frequency power is efficiently supplied to a high frequency electrode.

1 is a perspective view illustrating a discharge cell structure of a high frequency plasma display panel.

2 is a waveform diagram showing a drive signal supplied to each electrode of a high frequency plasma display panel;

3 is a view showing a driving device for turning on / off a sustain discharge in a high frequency plasma display panel according to the prior art;

4 is a diagram illustrating a driving device for turning on / off a sustain discharge in a high frequency plasma display panel according to an exemplary embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

20: lower substrate 22, 92: data electrode

24: dielectric layer 26, 90: scan electrode

28: partition 30: phosphor

32: upper substrate 34,84: high frequency electrode

36: discharge area 60, 80: high frequency generator

62,88: impedance matching unit 64: switch

66,82: Plasma Display Panel

86: first switch 94: second switch

96: impedance correction capacitor 98: switch control unit

100: inverter

In order to achieve the above object, a driving apparatus of a high frequency plasma display panel according to the present invention includes a display panel discharged by a high frequency signal, a high frequency generator for generating the high frequency signal, and a high frequency electrode for impedance matching of the display panel. An impedance matching unit connected to an input terminal, a first switch connected between the high frequency generating unit and the impedance matching unit to switch the high frequency signal to be supplied to the high frequency electrode, the first switch, the high frequency generating unit and the display panel And an impedance correction means for compensating for a lower input impedance value of the high frequency electrode input terminal to which the high frequency signal is supplied than when the sustain discharge is turned on and when the sustain discharge is turned on. Capacitor connected between scan electrode of panel and ground voltage source A second switch connected to the ground terminal of the high frequency generator, a scan electrode and a capacitor of the display panel to switch the high frequency signal, a switch controller connected to the first and second switches to control the switch, and the switch And an inverter connected between the control unit and the second switch such that the control signal of the second switch supplied from the switch control unit is reversed from the first switch. The driving method of the high frequency plasma display panel according to the present invention is a high frequency signal. A method of driving a high frequency plasma display panel in which a sustain discharge is caused by a method, the method comprising: connecting an impedance compensation capacitor to the display panel in parallel so as to compensate an impedance value of the display panel which is reduced relative to the sustain discharge period; The impedance in the period except discharge And opening the compensation capacitor. Other objects and features of the present invention will become apparent from the description of the embodiments with reference to the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described with reference to FIG. 4.

4 is a view showing a driving apparatus according to an embodiment of the present invention for turning on / off a sustain discharge in an RF PDP. Referring to FIG. 4, the driving apparatus according to the present invention is a high frequency generator (10) for generating a high frequency signal ( 80, an impedance matching unit 88 connected to the input terminal of the high frequency electrode 84 of the PDP 82, and a first switch 64 connected between the high frequency generator 80 and the impedance matching unit 88; And a second switch 94 and an impedance correction capacitor 96 connected in parallel between the scan electrode 90 of the PDP 82 and the ground terminal GND of the high frequency generator 80, and the first and second electrodes. The switch control part 98 which supplies a switching control signal to the switches 86 and 94, and the inverter 100 connected between the 2nd switch 94 and the switch control part 98 are provided.

The impedance matching unit 88 serves to match Z _S to Z _IN so that maximum power is supplied to the high frequency electrode 84. The first switch 86 switches the supply of the high frequency signal from the high frequency generator 80 to the high frequency electrode 84 of the PDP 82 according to the switching control signal of the switch control unit 98. The switching control signal generated from the switch controller 98 and inverted by the inverter 100 is supplied to the second switch 94 to be reversed from the first switch 86. Accordingly, when the first switch 86 is turned on, the second switch 94 is turned off, and when the first switch 86 is turned off, the second switch 94 is turned off. Switch 94 is turned on. The scan electrode 90 serving as the ground electrode of the high frequency electrode 84 during the sustain discharge by the switching of the second switch 94 is directly connected to the ground terminal GND or through the impedance correction capacitor 96. GND).

In the driving apparatus of the RF PDP according to the present invention, the second switch 94 and the impedance correction capacitor 96 further provided for the conventional driving apparatus are provided between Z _IN and Z _S irrespective of whether the sustain discharge is on or off. Impedance matching is always performed so that high frequency power can be efficiently supplied to the high frequency electrode 84. [0025] In detail, first, the first switch 86 is turned on by the control signal of the switch controller 98. When the second switch 94 is turned off, a high frequency signal is supplied to the high frequency electrode 84 of the PDP 82. At this time, sustain discharge occurs in the PDP 82, and the impedance of the panel itself has a Z _ON value. Since the second switch 94 is turned off, the scan electrode 90 of the PDP 82 is connected to the ground terminal GND through the impedance correction capacitor 96. Then, during sustain discharge, Z _ON and the correction impedance (hereinafter, referred to as 'Z _CAP ') by the impedance correction capacitor 96 are connected in series, so the input impedance Z _IN seen from the input terminal of the high frequency electrode 84 is Z _ON + will have a value of Z _CAP the first switch 86 by switch control unit 98 is turned on. impedance does not cause sustain discharge in the oFF-state panel itself has a Z value _oFF. In this case, since the second switch 94 is turned on, the scan electrode 90 is directly connected to the ground terminal GND of the high frequency generator 80 through the second switch 94. In other words, when sustain discharge does not occur, no influence is caused by the impedance correction capacitor 96. Then, the input impedance Z _IN seen at the high frequency electrode input terminal when no sustain discharge occurs has a Z _OFF value. As a result, Z _ON has a smaller value than Z _OFF because the capacitance value is larger than the case where sustain discharge does not occur during sustain discharge. In the present invention, when the value of Z _ON + Z _CAP during sustain discharge does not occur, When the capacitance value of the impedance correction capacitor 96 is set to be equal to the Z _OFF value of, Z _IN is always maintained at a constant value regardless of whether sustain discharge is on or off, and high frequency power is supplied to the high frequency electrode 84. It can supply efficiently. That is, if the impedance matching unit 88 is designed such that the source impedance Z _S is matched with respect to Z _IN which always maintains a constant value regardless of the on / off of sustain discharge, the high frequency supplied at turn-on of the first switch 86 Power is efficiently supplied without being reflected at the input of the high frequency electrode 84.

The capacitance value of the impedance correction capacitor 96 (hereinafter referred to as 'C _CAP ') is set as follows. First, the panel impedance Z _ON when sustain discharge is occurring in the absence of the impedance correction capacitor 96 is measured, and the corresponding panel capacitance C _ON is calculated. In this case, the panel impedance Z _ON may be calculated by a method of measuring the power supplied from the high frequency generator 80 and the voltage applied to the high frequency electrode 82. Next, measure the panel impedance Z _OFF when no sustain discharge occurs and calculate the corresponding panel capacitance C _OFF . With the impedance correcting capacitor 96, Z _ON + Z _CAP should be equal to Z _OFF . Since impedance and capacitance are inversely related, the C _CAP value should be set to satisfy the relationship of 1 / C _ON + 1 / C _CAP = 1 / C _OFF . For example, assuming that the panel capacitance C _ON value at the sustain discharge is 200 Hz, and the panel capacitance C _OFF value at the sustain discharge is 100 Hz, the capacitance C _CAP of the impedance correction capacitor 96 added in the present invention is Should have 200 ㎊.

As described above, the driving apparatus of the high frequency plasma display panel according to the present invention can efficiently supply high frequency power to the high frequency electrode by constantly maintaining the input impedance at the input terminal of the high frequency electrode regardless of the on / off state of sustain discharge. There are advantages to it.

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 (5)

In a driving device of a high frequency plasma display panel in which sustain discharge is caused by a high frequency signal, A display panel discharged by a high frequency signal, A high frequency generator for generating the high frequency signal; An impedance matching unit connected to a high frequency electrode input terminal for impedance matching of the display panel; A first switch connected between the high frequency generator and an impedance matching unit to switch the high frequency signal to be supplied to the high frequency electrode; An impedance correction means connected to the first switch, the high frequency generator, and the display panel to compensate for a lower input impedance value of the high frequency electrode input terminal to which the high frequency signal is supplied than when the sustain discharge is on; A drive device for a high frequency plasma display panel, comprising: The method of claim 1, The impedance correction means A capacitor connected between the scan electrode of the display panel and a ground voltage source; A second switch connected to a ground terminal of the high frequency generator, a scan electrode of the display panel, and a capacitor to switch the high frequency signal; A switch control unit connected to the first and second switches to control the switch; And an inverter connected between the switch control unit and the second switch to switch the control signal of the second switch supplied from the switch control unit to the opposite side of the first switch. In a driving method of a high frequency plasma display panel in which sustain discharge is caused by a high frequency signal, Connecting an impedance compensation capacitor in parallel to the display panel to compensate for the impedance value of the display panel which is reduced relative to the sustain discharge period; And opening the impedance compensation capacitor in the remaining period except for the sustain discharge. The method of claim 3, wherein And the impedance compensating capacitor is connected to a scan electrode of the display panel. The method of claim 4, wherein The opening of the impedance compensation capacitor may include switching between the scan electrode of the display panel and the impedance compensation capacitor for a period other than the sustain discharge, and connecting the scan electrode to the base voltage source. How to drive the panel.