KR100596239B1 - Device for Driving Plasma Display Panel - Google Patents

Abstract

The present invention relates to a plasma display panel, and more particularly, to a driving apparatus of a plasma display panel.

In order to achieve the above object, the present invention provides a driving apparatus for a plasma display panel which applies a scan pulse and a sustain pulse to a Y electrode (scan electrode) and applies a sustain pulse alternated with the sustain pulse to a Z electrode (sustain electrode). A scan reference voltage supply unit configured to apply a ramp-up pulse to the Y electrode (scan electrode); A set down voltage supply unit applying a ramp down pulse during a set down period of a reset section; A scan voltage supply unit configured to switch in response to a timing control signal during an address period of a subfield to supply a scan pulse; A drive unit to receive a voltage signal from the scan reference voltage supply unit, the setdown voltage supply unit, and the scan voltage supply unit; And a peak voltage canceling unit for removing a peak voltage applied to the scan reference voltage supply unit through a Y electrode (scan electrode) due to a data pulse applied to the X electrode (data electrode).

As described above, the present invention has an effect of suppressing heat generation of the device generated in a specific data pattern.

PDP drive, heat generation, alternative pattern, displacement current

Description

Device for driving plasma display panel {Device for Driving Plasma Display Panel}

1 is a block diagram of a driving apparatus of a general plasma display panel.

2 is a circuit diagram of a scan driving device of a conventional Y electrode (scanning electrode) driving unit.

3 is a circuit diagram of a scan driving apparatus according to an embodiment of the present invention;

***** Explanation of symbols for main parts of drawing *****

100: peak voltage rejection

The present invention relates to a plasma display panel, and more particularly, to a driving apparatus of a plasma display panel.

1 is a block diagram of a driving apparatus of a general plasma display panel.

As shown in FIG. 1, the signal processor 110 converts an externally input image signal into image data suitable for driving a plasma display panel.

The data aligner 120 rearranges the image data converted by the signal processor 110 for each subfield.

The X electrode (data electrode) driving unit 130 and the Y electrode (scan electrode) driving unit 140 respectively transmit an address pulse and a scan pulse to form a wall voltage in the discharge cell of the plasma display panel. The Y electrode (scan electrode) driver 140 and the Z electrode (sustain electrode) driver 150 apply a sustain pulse alternately to sustain the discharge of the discharge cell in which the wall voltage is formed. It is applied to an electrode (scan electrode) and a Z electrode (sustain electrode).

The main controller 160 controls the image data rearranged to the data alignment unit 120 in order according to the external image signal to be supplied to the X electrode (data electrode) driver 130 by one scan line, and controls the logic. The pulse is applied to the high voltage driving circuit unit 170.

Fig. 2 is a diagram showing a circuit of a scan driving device of a conventional Y electrode (scan electrode) driving unit.

The scan driving device of the Y electrode (scan electrode) driving unit includes a scan reference voltage supply unit 50, a driver unit 52, a set-down voltage supply unit 47, and a scan voltage supply unit 46.

The scan reference voltage supply unit 50 includes a third capacitor c3 connected between the reference voltage source Vsc and the second node n2, and Vsc connected between the reference voltage source Vsc and the second node n2. Switch Q8 and Nsc switch Q9.

The Vsc switch Q8 supplies the drive unit 52 with the voltage of the reference voltage source Vsc by the control signal supplied from the main controller 160 during the address period. The ninth switches Q9 and Nsc serve to hold the voltage applied to the circuit to ground during the reset period and the sustain period.

The set-down supply unit 47 includes a tenth switch Q10 connected between the second node n2 and the scan voltage −Vy. The set-down supply unit 47 gradually lowers the voltage supplied to the drive unit 52 with a slope to the scan voltage (−Vy) during the set-down period included in the reset period of the subfield.

The scan voltage supply 46 has an eleventh switch Q11 connected between the second node n2 and the scan voltage source. The eleventh switch Q11 is switched in response to a control signal supplied from a timing controller (not shown) during the address period to supply the scan voltage -Vy to the drive unit 52.

In the structure of the AC PDP as described above, when a voltage is applied to the X electrode (data electrode) which is the data electrode, the data voltage is applied to the capacitor 60 between the XY electrodes (scan electrodes) of the panel due to the change of the high level and the low level state. The displacement current flows, and this displacement current is induced to other electrodes (Y and Z electrodes (sustain electrodes)).

In other words, the change of the data voltage affects the other capacitors and the resistance on the circuit, which causes the peak component of the voltage to be induced in the driving portion of the other electrode.

When an alternative pattern, which is a pattern in which one line of the PDP is discharged and the next line is not discharged, is applied to the panel, the displacement current due to the change of the data voltage appears somewhat larger, which has a greater effect on the output waveform of the other electrode. Get mad.

In addition, since the displacement current has a large peak value, a problem occurs that damages the switching element of the driving circuit.

When the alternative pattern as described above is applied to the address electrode (the X electrode (data electrode)), the displacement current due to the data voltage ripple component is caused by the capacitance 60 between the XY electrodes (the scan electrode). It is induced through) and affects the Vsc switch Q8 which repeats on and off during the scan period.

In other words, while the data voltage is repeatedly turned on and off in a short cycle, the peak component of the voltage is induced to the Y electrode (scan electrode) to generate a large ripple voltage in the scan voltage output waveform.

The ripple component caused by the voltage peak component affects the elements of the driving circuit such as the Vsc switch Q8, the resistor, and the -Vy switch Q11, causing a heat generation problem in which the temperature rises rapidly.

The heat generation problem of the device causes a problem in the operation of the PDP.

The present invention is to solve the above-mentioned problems, the plasma display panel driving apparatus that can suppress the heat generation of the device generated when the data signal is applied to the X electrode, and the heat generation phenomenon of the device more problematic in a specific data pattern To provide.

In order to achieve the above object, the present invention provides a driving apparatus for a plasma display panel which applies a scan pulse and a sustain pulse to a Y electrode (scan electrode) and applies a sustain pulse alternated with the sustain pulse to a Z electrode (sustain electrode). A scan reference voltage supply unit configured to apply a ramp-up pulse to the Y electrode (scan electrode); A set down voltage supply unit applying a ramp down pulse during a set down period of a reset section; A scan voltage supply unit configured to switch in response to a timing control signal during an address period of a subfield to supply a scan pulse; A drive unit to receive a voltage signal from the scan reference voltage supply unit, the setdown voltage supply unit, and the scan voltage supply unit; And a peak voltage canceling unit for removing a peak voltage applied to the scan reference voltage supply unit through a Y electrode (scan electrode) due to a data pulse applied to the X electrode (data electrode).

The scan reference voltage supply unit may include a Vsc switch for applying a scan reference voltage according to a switching operation, and an Nsc switch for holding a ground of the driving voltage in a reset section and a sustain section, and the peak voltage canceller includes a capacitor. And one end of the capacitor is connected to the source end of the Vsc switch, and the other end of the capacitor is connected to the source end of the Nsc switch.

In addition, the capacitor is characterized in that it has a capacity of less than 1uF.

Hereinafter, with reference to the accompanying drawings, a specific embodiment according to the present invention will be described.

<Example>

3 is a diagram illustrating a circuit of a scan driving apparatus according to an embodiment of the present invention.

The Y electrode (scan electrode) scan pulse driving apparatus shown in FIG. 3 includes a scan reference voltage supply unit 50, a setdown voltage supply unit 47, a scan voltage supply unit 46, a driver unit 52, and a peak voltage eraser ( 100).

The scan reference voltage supply unit 50 applies a ramp-up pulse to the Y electrode (scan electrode).

The set down voltage supply unit 47 applies a ramp down pulse during the set down period of the reset section.

The scan voltage supply unit 46 switches in response to the timing control signal during the address period of the subfield to supply the scan pulse.

The driver unit 52 receives a voltage signal from the scan reference voltage supply unit 50, the set down voltage supply unit 47, and the scan voltage supply unit 46.

The peak voltage eraser 100 removes the peak voltage applied to the scan reference voltage supply unit 50 through the Y electrode (scan electrode) due to the data pulse applied to the X electrode (data electrode).

In the case of the conventional PDP, when an alternative pattern, which is a pattern in which one line is discharged and the next line is not discharged, is applied to the panel, the displacement current due to the change in the data voltage appears slightly larger than in the case of a general video signal. This will have a greater effect on the output waveform of the electrode.

When such an alternative pattern is applied to the address electrode (the X electrode (data electrode)), the data voltage ripple component is largely generated by the capacitance 60 between the XY electrodes (scan electrodes), and the displacement due to the ripple component is caused. Current is induced through the scan driver 52 to affect the Vsc switch Q8 and the Nsc switch Q9 of the scan reference voltage supply unit 50.

The Vsc switch Q8 applies a scan reference voltage to the Y electrode (scan electrode) in the scan section according to the switching operation, and the Nsc switch Q9 grounds the voltage applied to the circuit in the reset section and the sustain section. It serves as a catch.

That is, the ripple component generated by the induced peak component affects the scan reference voltage supply unit 50, so that the temperature of the switch element in the scan reference voltage supply unit 50 increases rapidly.

Due to the heat generation problem of such a device causes a problem of lowering the operation characteristics of the PDP.

In order to improve the heat generation problem in the alternative pattern as described above, the present invention includes a peak voltage canceller 100 between the scan reference voltage supply unit 50 and the drive unit 52.

The peak voltage canceller 100 includes a capacitor, one end of the capacitor is connected to the source terminal of the Vsc switch Q8, and the other end of the capacitor is connected to the source terminal of the Nsc switch Q9. It is possible to be connected.

By connecting a capacitor having a small capacitance to the peak voltage canceller 100, the ripple voltage component induced by the address electrode is removed.

As a result, the operation reliability of the driving circuit can be improved by removing the ripple voltage component induced in the scan reference voltage supply unit 50 to improve the driving problem caused by the heating of the device.

By adding a capacitor at the position as described above, the ripple component supplied to the scan reference voltage supply unit 50 through the drive unit 52 can be removed to stabilize the driving of the PDP more, and it is possible to solve the heat generation problem of the device. .

In addition, the capacitor preferably has a capacity of 1 uF or less.

The use of capacitors with small capacitances of less than 1uF is advantageous to improve the operational reliability of the drive circuit.

In fact, the DC voltage is not applied to the driving circuit but the pulse type AC voltage is applied to drive the AC PDP. When a large capacitor is added to the peak voltage canceller 100, only the ripple voltage component is removed. This affects the voltage component required for operation.

When the voltage rises by the Vsc voltage to scan the Y electrode (scan electrode) after the last set-down period of the reset period of the AC PDP driving waveform, the slope of the voltage increases rapidly.

However, when a capacitor of 1uF or more is used on the peak voltage canceller 100, the slope of the rising voltage becomes gentle, which causes a problem in the normal driving of the PDP.

Therefore, since the use of a capacitor having a large capacitance of 1 uF or more is highly likely to cause a problem in the waveform of the PDP driving itself, it is preferable to include a capacitor of 1 uF or less in the peak voltage canceller 100.

According to an embodiment of the present invention, when a capacitor having a capacitance of about 200 nF or 100 nF is used for the peak voltage canceller 100, the voltage switching component of the X electrode (data electrode) in the alternative pattern is set to the Y electrode (scan electrode). The peak voltage induced in the direction of the Vsc switch can be sufficiently weakened.

As a result, the present invention can solve the heat generation problem while eliminating the ripple component of the voltage generated at the X electrode (data electrode), thereby improving the operating characteristics.

As such, the technical configuration of the present invention described above can be understood by those skilled in the art that the present invention can be implemented in other specific forms without changing the technical spirit or essential features of the present invention.

Therefore, the above-described embodiments are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the appended claims rather than the detailed description, and the meaning and scope of the claims and All changes or modifications derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

As described above, the present invention has an effect of suppressing heat generation of the device generated in a specific data pattern.

Claims (3)

A driving apparatus of a plasma display panel which applies a scan pulse and a sustain pulse to a Y electrode (scan electrode), and applies a sustain pulse alternated with the sustain pulse to a Z electrode (sustain electrode). A scan reference voltage supply unit applying a ramp-up pulse to the Y electrode (scan electrode); A set down voltage supply unit applying a ramp down pulse during a set down period of a reset section; A scan voltage supply unit configured to switch in response to a timing control signal during an address period of a subfield to supply a scan pulse; A drive unit to receive a voltage signal from the scan reference voltage supply unit, the setdown voltage supply unit, and the scan voltage supply unit; And And a peak voltage canceling unit for removing the peak voltage applied to the scan reference voltage supply unit through the Y electrode (scan electrode) due to the data pulse applied to the X electrode (data electrode). drive. The method of claim 1, The scan reference voltage supply unit includes a Vsc switch for applying a scan reference voltage according to a switching operation, and an Nsc switch for holding a ground of the driving voltage in a reset section and a sustain section. The peak voltage canceller comprises a capacitor, One end of the capacitor is connected to the source end of the Vsc switch, And the other end of the capacitor is connected to the source end of the Nsc switch. The method of claim 2, The capacitor, A drive device for a plasma display panel having a capacity of 1 uF or less.

Images