KR20020033664A - Driving method and system for improving both luminance and luminous efficiency in ac pdp - Google Patents

Abstract

PURPOSE: A driving method and a driving apparatus are provided, which increase a brightness and a luminescence efficiency of an AC type plasma display panel(PDP) at the same time by applying a sustain voltage to a sustain electrode and at the same time by applying a positive voltage to an address electrode. CONSTITUTION: The plasma display panel(PDP) has a number of cells to display an image, and each cell constitutes one frame with a plurality of sub fields to display a gray level in the PDP having an address electrode and a pair of sustain electrodes. And each sub field is constituted with an initialization period, an address period and a sustain period. The driving method of the PDP includes a step of generating a sustain discharge by applying a voltage between the sustain electrodes, and a step of increasing a discharge volume by applying a positive voltage to the address electrode during at least a part of the period when the sustain discharge continues. The voltage applied to the address electrode is turned off before wall charges are accumulated on the sustain electrode in order not to hinder the formation of the wall charges by a discharge between the sustain electrodes.

Description

DRIVING METHOD AND SYSTEM FOR IMPROVING BOTH LUMINANCE AND LUMINOUS EFFICIENCY IN AC PDP}

The present invention relates to a method and apparatus for driving during a sustain period for increasing luminance and luminous efficiency of an alternating plasma display panel (PDP). The present invention relates to a method and apparatus for increasing luminance and luminous efficiency by inducing a discharge having a larger volume inside a discharge cell by applying a positive voltage to an address electrode while a sustain discharge is applied by applying a voltage for discharge.

1 is a perspective view of the upper and lower plates of a typical AC surface discharge PDP separated. In FIG. 1, the front substrate 10 displaying information and the rear substrate 20 positioned in parallel with the same width as the front substrate 10 are formed. The front substrate 10 is composed of a transparent electrode 60 and a bus electrode 70 having a low resistivity, and a plurality of sustain electrode lines for applying a voltage waveform, and a dielectric layer 80 formed between the sustain electrode lines to limit discharge current. And a protective layer 90 formed on the dielectric layer 80 to protect the sustain electrode line. The back substrate 20 includes a plurality of partition walls 30 forming a discharge space, a plurality of address electrode lines 40 formed so as to be orthogonal to the storage electrode lines between the partition walls 30, and each discharge space has both sides of an inner surface thereof. It is formed to surround the address electrode line 40 on the barrier rib surface and the back substrate surface, and is composed of a fluorescent layer 50 that receives the vacuum ultraviolet (VUV) generated during discharge and emits visible light.

2 is a driving waveform diagram applied to each electrode of a general AC PDP. FIG. 2 illustrates voltage waveforms applied to the sustain electrode line and the address electrode line 40 including the transparent electrode 60 and the bus electrode 70 of FIG. 1 in order to display information on an AC PDP. It can be divided into an erase period T1, a write period T2, and a sustain period T3. In the erasing period T1, low and long pulses and high pulses are alternately applied to the sustain electrode lines X and Y to make the entire uneven panel uniform while the AC PDP displays the previous information, and the writing period T2. ), Information to be displayed by the voltage difference between one storage electrode line X and the address electrode line Z is written by stacking wall charges after write discharge, and in the sustain period T3, both storage electrode lines X and Y The alternating voltage is applied to cause only visible cells to be emitted in the writing period T2 to display the information. In the sustain period T3, the waveforms of the X and Y pulses, which are both sustain electrode lines, are square waves, and are mainly applied by changing the frequency or duty ratio of the sustain pulses depending on the driving method. At this time, no voltage is applied to the address electrode.

3 is a wall charge model diagram when a general square wave sustain pulse is applied. In Fig. 3, Fig. 3A shows the wall charge distribution after information is written in a manner of stacking wall charges in the writing period T2. When the sustain voltage Vs is applied to one sustain electrode, a sustain discharge such as (b) occurs near the front substrate surface between the rest of the sustain electrodes by the sum of the externally applied voltage and the wall voltage. The electric charges generated during the discharge process are accumulated as wall charges of opposite polarity under the sustain electrode by the electric field applied from the outside, and thus the electric field is canceled, and the discharge is rapidly extinguished as shown in (c). At this time, the metastable particles and some space charge remain and disappear as time passes (d). On the other hand, even if the sustain voltage Vs applied to one of the sustain electrodes is lost, the distribution of wall charges does not change as shown in (e), and if the sustain voltage Vs is applied to the other sustain electrode again, the next (f) The sustain discharge is generated, and the sustain discharge is continuously maintained as this process is repeated.

FIG. 4 is a waveform diagram illustrating temporal changes of voltage, current, and infrared rays in a typical square wave sustain pulse. In FIG. 4, since the infrared ray I is generated on the same reaction path as the vacuum ultraviolet ray VUV generated during the discharge, it is possible to track the temporal change of the vacuum ultraviolet ray VUV. In the rising part of the sustain pulse, a structural characteristic of the PDP in which the sustain electrode is covered with a dielectric material, and after the displacement current P1 corresponding to charging flows for the period T4 of FIG. 4, the sustain discharge is generated by the sum of the external applied voltage and the wall voltage. While the discharge current P2 flows and infrared light is emitted during the T5 period. After the sustain discharge, the discharge is rapidly extinguished by the wall charge, and there is no change in the current C and the infrared ray I during the T6 period. In the falling portion of the sustain pulse, the displacement current P1, which is caused by the structural features of the PDP, flows again. By the way, in order to improve the low luminous efficiency using the above-described general AC PDP, it is necessary to improve in the sustaining section that consumes the most power while actually emitting light, but in general, it has a low luminous efficiency by applying only a simple square wave. There is a problem.

Accordingly, the present invention is to solve such a problem, the present invention is not a discharge generated only on the front substrate surface as in the conventional surface discharge type PDP, but to the sustain electrode to generate a large discharge using most of the entire discharge space It is an object of the present invention to provide a method and apparatus for simultaneously increasing the luminance and luminous efficiency of an AC PDP by applying a sustain voltage and simultaneously applying a positive voltage to an address electrode for a predetermined period of time.

1 is a perspective view of the upper and lower plates separated from the general AC type surface discharge PDP;

2 is a driving waveform diagram applied to each electrode of a general AC PDP;

3 is a space charge and wall charge model diagram when a typical square wave sustain pulse is applied;

FIG. 4 is a waveform diagram illustrating temporal changes of voltage, current, and infrared rays in a typical square wave sustain pulse; FIG.

5 is a space charge and wall charge model diagram when a sustain waveform is applied for increasing luminance and luminous efficiency of an AC PDP according to the present invention;

FIG. 6 is a waveform diagram illustrating temporal changes of voltage, current, and infrared rays in a sustain waveform for increasing luminance and luminous efficiency of an AC PDP according to the present invention;

7 is a waveform diagram showing various types of sustain waveforms for increasing luminance and luminous efficiency of an AC PDP according to the present invention;

8 is a schematic diagram of a discharge during a sustaining period in a driving method of a general AC PDP;

9 is a voltage waveform diagram applied to each electrode during a sustaining period in a driving method of a general AC PDP;

10 is a discharge model diagram when applying an address waveform for increasing luminance and luminous efficiency of an AC-type PDP according to the present invention;

11 is a voltage waveform diagram applied to each electrode when an address waveform for increasing luminance and luminous efficiency of an AC PDP according to the present invention;

12 is a voltage waveform diagram applied to each electrode when a sustain waveform and an address waveform are applied for increasing luminance and luminous efficiency of an AC PDP according to the present invention;

13 is a circuit diagram of a driving device for generating a sustain waveform and an address waveform for increasing the luminance and luminous efficiency of an AC PDP according to the present invention;

<Explanation of symbols for the main parts of the drawings>

10: front substrate 20: rear substrate

30: partition 40: address electrode line

50: phosphor 60: transparent electrode

70 bus electrode 80 dielectric layer

90: protective layer

An AC PDP driving method according to an aspect of the present invention for achieving the above object, has a plurality of cells (cell) for representing an image, each cell having an address electrode and a pair of sustain electrodes One frame is formed of a plurality of subfields for gray scale representation in the plasma display panel, and the subfields are driving methods during the sustain period of the AC type plasma display panel, which are composed of an initialization period, an address period, and a sustain period again. Applying a voltage between the sustain electrodes to cause sustain discharge; And increasing a discharge volume by applying a predetermined positive voltage to the address electrode during at least a portion of the sustain sustain period.

An AC-type PDP driving apparatus according to another aspect of the present invention has a plurality of cells for representing an image, each cell having a gray level in a plasma display panel having an address electrode and a pair of sustain electrodes. One frame is composed of a plurality of subfields for representation, and the subfields are devices for driving during the sustaining period of the AC plasma display panel including the initialization period, the address period, and the sustain period, and between the sustain electrodes. Means for applying a voltage to cause sustain discharge; And means for increasing a discharge volume by applying a predetermined positive voltage to the address electrode during at least some of the sections in which the sustain discharge is sustained.

Preferably, the voltage applied to the address electrode is turned off before the wall charge is accumulated on the sustain electrode so as not to interfere with the formation of the wall charge accumulated on the sustain electrode by the discharge between the sustain electrodes. off).

Preferably, the voltage applied to the address electrode is a voltage in the form of a pulse.

Preferably, the voltage applied to the sustain electrode is a voltage in the form of a pulse.

Preferably, the voltage applied to the sustain electrode has a waveform in which a ramp wave is superimposed on an upper end of the pulse-shaped voltage.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are denoted by the same reference numerals as much as possible even if displayed on the other drawings. The effects of the ramp-type sustain pulse applied to the sustain electrode and the narrow, low-voltage pulse applied to the address electrode have been described separately.

5 is a space charge and wall charge model diagram when a ramp waveform is applied to a sustain electrode in order to increase luminance and luminous efficiency of an AC PDP according to the present invention. At this time, no voltage is applied to the address electrode.

In FIG. 5, FIG. 5A shows the wall charge distribution after the writing period T2. When the sustain voltage Vs is applied to one sustain electrode, sustain discharge occurs as shown in (b). Wall charges of opposite polarity begin to accumulate. In this case, when the applied sustain voltage Vs is constantly raised to prevent the electric field from being canceled by the wall charge, the electric field may be continuously applied into the discharge space. If the electric field is continuously applied inside the discharge space, energy can be maintained for a long time by applying energy to the particles in metastable states as shown in (c), (d) and (e), and at the same time, the space charge is additionally converted into wall charge. .

In the falling portion of the sustain pulse, the overcharged wall charges can cause discharge again with only the wall charges, resulting in self-erase discharges as shown in (f). After the self-erasing discharge, the electric charges exist only as space charges as in (g) because no electric field is applied from the outside. If the sustain voltage Vs is applied from the outside before the space charges disappear, a sustain discharge using the space charge and the external applied voltage is generated as shown in (h), and the sustain discharge is continuously maintained as this process is repeated.

FIG. 6 is a waveform diagram illustrating temporal changes of voltage, current, and infrared rays when a sustain waveform is applied for increasing whiteness and luminous efficiency of an AC PDP according to the present invention.

In Fig. 6, after the displacement current P1 as in T8 in Fig. 6 flows in the rising portion of the sustain pulse, the discharge current P2 flows and the infrared ray I begins to be emitted as in T9. At this time, if the sustain voltage Vs is constantly raised, the discharge can be maintained for a long time by using the metastable particles, and the emission of infrared ray I is maintained for a long time, and the discharges are used because the metastable particles are used. The current P2 flows only a very small amount compared to the current when the discharge is started, such as T10. At the same time, space charge is additionally converted into wall charge as in T11. In the falling portion of the sustain pulse, after the displacement current P1 flows as T12, a self-erasing discharge is generated so that no current flows but only the infrared rays I are emitted as in T13.

As described above, in the long-term discharge generated at the rising portion of the sustaining pulse in terms of luminous efficiency, since the metastable particles are used, only a small amount of power is consumed compared to the emission amount of the infrared rays (I). In the generated self-erasing discharge, since only the wall charge is discharged, infrared (I) is emitted without consuming additional power.

FIG. 7 is a waveform diagram illustrating various sustaining waveforms for increasing luminous efficiency of an AC PDP according to the present invention. FIG. 7A shows waveforms of the ramp-shaped square wave. (B) utilizes only the self-erasing discharge effect, (c) utilizes only the effect of increasing the discharge time when the sustain waveform rises, and (d) the waveform shows the space charge at various sustain pulse frequencies when using the self-erasing discharge. (E) shows the waveform for preventing the mis-discharge caused by the high voltage when the lamp-shaped square wave is applied.

8 is a schematic diagram of space charge and wall charge when a general PDP sustain pulse waveform is applied and no voltage is applied to the address electrode.

In FIG. 8, FIG. 8A shows the wall charge distribution after the writing period T2. When the sustain voltage Vs is applied to one sustain electrode, the entire discharge space cannot be used as shown in (b). The sustain discharge occurs only directly below the substrate, and wall charges of opposite polarity start to accumulate under the sustain electrode, and the discharge disappears as shown in (c). Thereafter, even if the sustain voltage disappears completely, it is stacked under the sustain electrode as shown in (d).

9 is a waveform diagram of voltages applied to each electrode when a general PDP sustain pulse waveform is applied and no voltage is applied to the address electrode.

In Fig. 9, V _S1 and V _S2 represent sustain pulses and V _A represents address pulses. When each section of FIG. 9 is associated with the diagram of FIG. 8, T14 corresponds to (a), T15 to (b), T16 to (c), and T17 to (d).

10 is a space charge and wall charge model diagram when an address pulse is applied to simultaneously increase luminance and luminous efficiency of an AC PDP according to the present invention.

In FIG. 10, FIG. 10A shows the wall charge distribution after the writing period T2. When a sustain voltage Vs is applied to one sustain electrode, a pulse is also applied to the address electrode at the same time. Likewise, in addition to the electric fields between the sustain electrodes, an electric field is generated between the sustain electrode and the address electrode, thereby attracting electrons generated during the sustain discharge toward the address electrode, thereby increasing the discharge volume as a whole, and transmitting the VUV to the fluorescent film much more efficiently. There is an increase in brightness and power consumption is no difference. After the sustain discharge, wall charges of opposite polarity start to accumulate under the sustain electrode, and the discharge disappears as shown in (c). If the pulse acting on the address electrode is applied until the wall charge starts to accumulate, it will interfere with the accumulation of the wall charge, and thus it must be applied until the wall charge starts to accumulate on the sustain electrode. At this time, since the electric field acts between the sustain electrode and the address electrode, the wall charges are accumulated in the address electrode as well as the two sustain electrodes. Thereafter, even if the sustain voltage disappears completely, it is stacked under the sustain electrode as shown in (d).

11 is a waveform diagram of voltages applied to each electrode when an address pulse for increasing luminance and luminous efficiency of the AC PDP according to the present invention is applied.

In FIG. 11, if each section of FIG. 11 is associated with the diagram of FIG. 10, T18 corresponds to (a), T19 corresponds to (b), T20 corresponds to (c), and T21 corresponds to (d).

12 illustrates an embodiment in which a ramp-type sustain pulse is applied to a sustain pulse waveform and a pulse is applied to an address electrode at the same time in order to increase the brightness and luminous efficiency of the AC PDP according to the present invention.

In Fig. 12, a long time discharge and a large volume discharge occur in T22, a space charge is converted into an additional wall charge in T23, and a self-erasing discharge occurs in T24. It is possible to increase the luminous efficiency. Here, the driving method proposed by the present invention according to the conditions of the panel or the driving conditions may be applied to the sustain electrode in the sustain period for emitting light to make an image on the PDP, or may be applied only to the address electrode. In addition, it can apply to a sustain electrode and an address electrode simultaneously.

FIG. 13 is a circuit diagram of a driving device capable of generating a waveform applied to each electrode in order to increase brightness and luminous efficiency of an AC PDP according to the present invention.

In Fig. 13, the sustain driving circuits (which are the same circuits as the C2 and C3: C2 circuits) are circuits C2-B which generate a ramp waveform to a circuit C2-A which generates a square wave which is an output of a general sustain driving circuit. Is a circuit for generating a lamp-shaped square wave proposed in the present invention. The address driving circuit C1 is a circuit for generating a waveform having a narrow pulse width and a low voltage in synchronization with the sustain pulse waveform in the sustain period so that the address electrode has the effect of the method proposed in the present invention.

As described above, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

As a result, using the driving method and apparatus according to the present invention in order to simultaneously increase the luminance and luminous efficiency of the AC-type PDP has the following advantages.

In other words, in order to increase the brightness and luminous efficiency of the AC-type PDP, while the sustain voltage is applied to the sustain electrode, a positive voltage is applied to the address electrode for a predetermined period of time, thereby attracting electrons generated during discharge toward the address electrode. The discharge can be induced, and the luminance and the light emitting efficiency can be increased because the volumetric discharge can increase the VUV generation efficiency and the transfer efficiency to the fluorescent film applied on the address electrode.

Claims (6)

A plurality of cells are used to represent an image, and each cell constitutes one frame with a plurality of subfields for gradation representation in a plasma display panel having an address electrode and a pair of sustain electrodes. In the driving method for the sustain period of the AC type plasma display panel composed of an initialization period, an address period and a sustain period again, Applying a voltage between the sustain electrodes to cause sustain discharge; And And increasing a discharge volume by applying a predetermined positive voltage to the address electrode during at least a portion of the sustain sustain period. The method of claim 1, The voltage applied to the address electrode is turned off before the wall charge is accumulated on the sustain electrode so as not to interfere with the formation of the wall charge accumulated on the sustain electrode by the discharge between the sustain electrodes. Driving method for increasing luminance and luminous efficiency of AC PDP. The method of claim 1, And a voltage applied to the address electrode is a pulse voltage. The method of claim 1, And a voltage applied to the sustain electrode is a pulse voltage. The method of claim 1, The voltage applied to the sustain electrode is a driving method for increasing the brightness and luminous efficiency of the AC-type PDP having a waveform of the form of the lamp wave superimposed on the upper end of the voltage of the pulse type. A plurality of cells are used to represent an image, and each cell constitutes one frame with a plurality of subfields for gradation representation in a plasma display panel having an address electrode and a pair of sustain electrodes. In the apparatus for driving during the sustain period of the AC type plasma display panel composed of the initialization period, the address period and the sustain period again, Means for applying a voltage between the sustain electrodes to cause sustain discharge; And And a means for increasing a discharge volume by applying a predetermined amount of voltage to the address electrode during at least a portion of the sustain sustain period.