Drive method and drive circuit for plasma display panel

In a drive method of a mixed scan-sustain type of plasma display panel, set-up discharge is performed in the next scan line to be scanned when any particular scan line is in a write period. At this time, a first set-up discharge pulse, which is a gradually rising pulse of the opposite polarity of the scan pulse, is applied to scan electrodes of the scan line that is in the set-up discharge period, and a second set-up discharge pulse, which is a rectangular or gradually rising pulse of the same polarity as the scan pulse and of lower voltage than the scan pulse, is applied to the sustain electrodes. In addition, a set-up discharge erase pulse for eliminating set-up discharge and a sustain erase pulse for eliminating sustain discharge are impressed with the same gradually falling pulse shape.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a method of driving a plasma display panel, and particularly to a method of driving an AC plasma display panel.

2. Description of the Related Art

Plasma display panels (hereinbelow abbreviated PDP ) typically offer many features including thin construction, lack of flicker, and a high display contrast ratio, and in addition are relatively amenable to large screen applications. They have a high response speed, and in emissive types can emit color visible lights using phosphors. As a result, plasma display panels increasingly are becoming widely used in recent years in the fields of computer-related display devices and color image display devices.

Depending on the mode of operation, PDP can be divided between an AC type, in which AC discharge occurs indirectly between electrodes that are covered by a dielectric material, and a DC type, in which discharge occurs by exposing electrodes in a discharge space.

The AC type can be further divided between the memory type that takes advantage of the memory effect of the display cells, and the refresh type that does not use the memory effect.

The luminance of the PDP is proportional to the number of discharges, i.e., the number of repeated pulses applied within a prescribed time interval (for example, one frame). Luminance drops as the capacitance of the display increases in the above-described refresh type, and this type is therefore chiefly used for a PDP having a low display capacitance.

The structure of a display cell of the above-described AC memory-type PDP is first described using FIG. 1 .

As shown in FIG. 1 , a display cell of an AC memory-type PDP is made up of: first insulating substrate 1 and second insulating substrate 2 that are composed of glass and provided on the rear and front surfaces of the panel; transparent scan electrodes 3 and sustain electrodes 4 that are formed on second insulating substrate 2 at a prescribed spacing; first trace electrodes 5 and second trace electrodes 6 that are each laminated so as to overlap over scan electrodes 3 and sustain electrodes 4 , respectively, so as to decrease the electrode resistance of scan electrodes 3 and sustain electrodes 4 ; first dielectric layer 12 that is formed to cover each of scan electrodes 3 , sustain electrodes 4 , first trace electrodes 5 , and second trace electrodes 6 ; protective layer 13 laminated on first dielectric layer 12 composed of, for example, magnesium oxide, for protecting first dielectric layer 12 from discharges; data electrodes 7 arranged on first insulating substrate 1 and formed in a direction that is orthogonal to scan electrodes 3 and sustain electrodes 4 ; second dielectric layer 14 formed to cover data electrodes 7 ; discharge gas space 8 that is formed between first insulating substrate 1 and second insulating substrate 2 and that is filled with a discharge gas composed of an inert gas such as helium, neon, or xenon, or a gas mixture of these gases; barrier ribs 9 provided on second dielectric layer 14 for both forming discharge gas spaces 8 and demarcating discharge cells; and phosphor 11 applied onto second dielectric layer 14 and to the sides of barrier ribs 9 for converting ultra-violet rays generated by discharge in discharge gas space 8 into visible light 10 .

In an actual PDP such as a color display panel for VGA, the above-described display cells are arranged in a lattice pattern with 480 display cells in the vertical direction and 1920 display cells in the horizontal direction, 480 scan electrodes 3 and 1920 sustain electrodes 4 being arranged corresponding to these cells.

The discharge in a PDP constructed as shown in FIG. 1 is next explained.

Discharge begins inside the display cell shown in FIG. 1 when a pulse voltage that exceeds the discharge threshold value is applied between scan electrode 3 and data electrode 7 , whereupon a positive or negative charge (wall charge) according to the polarity of this pulse voltage is attracted to and accumulated on the surface of first dielectric material 12 and second dielectric material 14 .

Since the equivalent internal voltage that is generated as a result of the accumulation of this charge, i.e., the wall voltage, is of the opposite polarity of the applied pulse voltage, the effective voltage inside the cell drops with the growth of discharge. Discharge therefore cannot be sustained and eventually stops even if the above-described pulse voltage is maintained at a fixed value.

Subsequent application of a sustain pulse, which is a pulse voltage of the same polarity as the wall voltage, between scan electrode 3 and sustain electrode 4 causes a build-up in the wall voltage as the effective voltage, which thereby exceeds the discharge threshold value to bring about discharge even if the voltage amplitude of the sustain pulse applied from the outside is small. In other words, discharge is sustained by continuing to apply sustain pulses between scan electrode 3 and sustain electrode 4 .

The above-described sustain discharge can be stopped by applying to scan electrode 3 or to sustain electrode 4 a sustain erase pulse, which is a either a wide low-voltage pulse or a narrow pulse of approximately the same voltage as the sustain pulse that serves to neutralize the wall voltage.

As shown in FIG. 2 , a PDP is a display panel capable of dot matrix display in which display cells 20 are arranged in a lattice of m rows and n columns. The PDP is provided with scan electrodes Sc 1 , Sc 2 , . . . Scm, and sustain electrodes Su 1 , Su 2 , . . . , Sum, that are arranged parallel to each other as row electrodes, and data electrodes D 1 , D 2 , . . . Dn that are arranged as column electrodes orthogonal to the scan electrodes and sustain electrodes.

When causing any display cell 20 to emit light, scan pulses are sequentially applied to scan electrodes Sc 1 , Sc 2 , . . . , Scm, and a data pulse that is in synchronism with the scan pulses is selectively applied to data electrode Di (1 i n) that is to emit light, thereby applying a voltage that exceeds the discharge threshold value (hereinbelow, referred to as writing display data ). Emission of light is then sustained by subsequently applying sustain pulses to sustain discharge between scan electrodes Sc 1 , Sc 2 , . . . Scm and sustain electrodes Su 1 , Su 2 , . . . , Sum.

As shown in FIG. 3 , the PDP drive circuit is made up of: scan electrode drive circuit 21 for applying pulse voltages to each of scan electrodes Sc 1 , Sc 2 , . . . , Scm; sustain electrode drive circuit 22 for applying pulse voltages to each of sustain electrodes Su 1 , Su 2 , . . . , Sum; data electrode drive circuit 23 for applying a voltage in accordance with image signals to each of data electrodes D 1 , D 2 , . . . , Dn; and control circuit 24 for outputting control signals to the drive circuit of each electrode based on basic signals (vertical synchronizing signals Vsync, horizontal synchronizing signals Hsync, display data signals DATA, and Clocks).

The vertical synchronizing signals Vsync prescribe the period of one frame; and the horizontal synchronizing signals Hsync are for establishing synchronization in the horizontal direction, similar to the horizontal synchronizing signals that are the control signal of a CRT (Cathode-Ray Tube). The display data signals DATA are signals for prescribing whether each display cell 20 is to emit light or not emit light in accordance with image signals, and the Clocks are signals synchronized with display data signals DATA for causing display data signals DATA to be taken into control circuit 24 .

Control circuit 24 is made up of: frame memory 25 for temporarily storing display data signals DATA; memory control unit 26 for reading display data signals DATA from frame memory 25 and transferring display data signals DATA to data electrode drive circuit 23 in accordance with the timing of writing to the PDP; driver control unit 28 for generating a drive waveform that corresponds to the PDP drive sequence and transferring to each of scan electrode drive circuit 21 and sustain electrode drive circuit 22 ; and signal processing unit 27 for regulating the operation of memory control unit 26 and driver control unit 28 and synchronizing the timing of the operation of each drive circuit.

Drive methods for an AC memory-type PDP include a separate scan-sustain type in which the application of sustain pulses to each scan line begins simultaneously after sequentially writing the display data of one frame (or one sub-field, to be explained hereinbelow) for each scan line, and the mixed scan-sustain type in which display data are sequential written for each scan line while sustain pulses are constantly applied to each display cell.

Referring to FIG. 4 , explanation is next presented regarding a prior-art PDP drive method taking the mixed scan-sustain type as an example. The PDP drive waveforms shown in FIG. 4 are described in Japanese Patent Laid-open No. 241528/1993. Wc 1 , Wc 2 , and Wc 3 are the pulse waveforms that are applied to scan electrodes Sc 1 , Sc 2 and Sc 3 ; Wu is the pulse waveform that is applied in common to sustain electrodes Su 1 , Su 2 , . . . , Sum; Wd is the pulse waveform that is applied to data electrodes D 1 , D 2 , . . . , Dn; and Id 1 is the emission waveform.

As shown in FIG. 4 , a sustain pulse of negative polarity is applied in common to each of sustain electrodes Su 1 , Su 2 , . . . , Sum in the mixed scan-sustain type of PDP drive method of the prior art.

Sustain pulses of negative polarity, in common with the pulses that are applied to sustain electrodes, are applied to each of scan electrodes Sc 1 , Sc 2 , . . . , Scm, and in addition, a sequential scan pulse (SP) and sustain erase pulse (EP) are also applied sequentially by scan electrode. Positive data pulses are applied to data electrodes D 1 , D 2 , . . . , Dn in accordance with display data.

To bring about light emission in the display cell at the intersection of scan electrode Sc 1 and data electrode D 1 , for example, a positive data pulse is applied to data electrode D 1 in synchronism with the scan pulse that is applied to scan electrode Sc 1 . A discharge is thus brought about in the display cell at the intersection of scan electrode Sc 1 and data electrode D 1 , and light is emitted as shown by waveform Id 1 . This discharge emission is sustained by continuing to apply sustain pulses to each of scan electrode Sc 1 and sustain electrode Su 1 , and halted by applying to scan electrode Sc 1 a sustain erase pulse of low voltage and narrow width.

In contrast with other display devices, however, gray-scale display is difficult to achieve by varying the applied voltage in a PDP, and gray-scale display is therefore typically achieved by controlling the number of emissions of light. In particular, a sub-field method such as shown in FIG. 5 is used to realize high-luminance gray-scale display. FIG. 5 shows an example of displaying 2 6 64 gray-scale levels.

In the sub-field method, as shown in FIG. 5 , one frame is divided into a plurality (six in FIG. 5 ) of sub-fields (SF 1 -SF 6 ) and a set-up discharge period, and a light emission time weight such as shown in FIG. 5 is conferred to each of these sub-fields. In FIG. 5 , the light emission time weights of each sub-field progress in order from SF 1 as: 2 5 , 2 4 , 2 3 , 2 2 , 2 1 , and 2 0 . Gray-scale display is realized by selecting emission or non-emission of light in each sub-field.

In the set-up discharge period, one discharge and erase (discharge halt) are first carried out in all display cells before writing display data to facilitate generation of write discharge by scan pulses and data pulses when all display cells are placed in an active state.

In the above-described PDP drive method, however, there is the problem of low utilization of time because other drive sequences must be suspended during the set-up discharge period. In particular, the time period that can be used for sub-fields is further limited in a case in which a plurality of set-up discharges are performed within one frame in order to allow stable generation of write discharge in sub-fields that are separated from the set-up discharge. As a result, the pulse width of the sustain pulses, scan pulses, and data pulses becomes shorter, and operation becomes unstable.

The above-described Japanese Patent Laid-open No. 241528/1993 discloses a method of minimizing the time lost in the set-up discharge periods in a case in which a plurality of set-up discharges are performed within one frame by making a sub-field that immediately precedes a set-up discharge period a sub-field with a smaller brightness weight, and moreover, altering the order of sub-fields (changing the order of weighting).

As another method of further decreasing the time lost in set-up discharge periods, Japanese Patent No. 2701725 discloses a method of performing set-up discharge on other scan lines while performing write discharge on any particular scan line.

In the method described in Japanese Patent No. 2701725, as shown in FIG. 6 , pulse train that differ by scan line are applied not only to scan electrodes Sc 1 , Sc 2 , . . . , Scm but to sustain electrodes Su 1 , Su 2 , . . . , Sum as well; pulse voltages being applied to each display cell in the order: set-up discharge pulse, set-up discharge erase pulse, scan pulse, sustain pulse, and sustain erase pulse; and in addition, the timing of application of scan pulses being sequentially shifted by scan line and a corresponding data pulses being applied to each data electrode.

In the technique described in Japanese Patent No. 2701725, however, the set-up discharge pulse and scan pulse are both of negative polarity, the data pulse is of positive polarity, and all of these pulses are rectangular waves, and as a result, strong discharge occurs not only at display cells at the intersections of scan electrodes to which scan pulses are applied and data electrodes to which data pulses are applied, but also at display cells at the intersections of sustain electrodes to which set-up discharge pulses are applied and data electrodes to which data pulses are applied that are synchronized with these set-up discharge pulses. The problem therefore arises that the set-up discharge causes the entire background brightness of the PDP to increase, and the background brightness further varies with the pattern of the image display.

A method is described in U.S. Pat. No. 5,745,086 for preventing increase in background brightness by applying a gradually rising set-up discharge pulse and weakening the intensity of the set-up discharge. The drive method described in U.S. Pat. No. 5,745,086, however, is an invention relating to the separated scan-sustain type of PDP drive method in which the set-up discharge period, write discharge period, and sustain discharge period are each entirely separated from each other, and discloses nothing relating to the mixed scan-sustain type of PDP drive method, such as the method described in Japanese Patent No. 2701725.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide a PDP drive method and drive circuit of the mixed scan-sustain type that reduces the time loss caused by set-up discharge period while suppressing increase in the background brightness caused by set-up discharge.

To achieve the above-described object according to the PDP drive method of the present invention, in a PDP drive method of the mixed scan-sustain type, when any particular scan line is in a write period, a set-up discharge is carried out in the scan line that is to be scanned next. At this time, a gradually rising first set-up discharge pulse that is of the opposite polarity of the scan pulses is applied to the scan electrodes of the scan line that is in a set-up discharge period, and a second set-up discharge pulse that is a rectangular or a gradually rising pulse of the same polarity as the scan pulse, and moreover, that is of lower voltage than the scan pulses, is applied to the sustain electrodes. The voltage of the second set-up discharge pulse in this case is a value such that discharge occurs with the first set-up discharge pulse, and such that discharge does not occur with a data pulse. In this way, the occurrence of discharge due to the set-up discharge pulse and a data pulse that is applied to data electrodes can be prevented, thereby preventing increase in the background brightness of the PDP.

Further, a set-up discharge erase pulse for eliminating set-up discharge and a sustain erase pulse for eliminating sustain discharge are applied with the same gradually falling pulse shape. The circuit for outputting the set-up discharge erase pulse and sustain erase pulse thus can be shared, thereby limiting increase in circuit scale.

Finally, one frame is divided into a plurality of sub-fields and all sub-fields within one frame are displayed by scan line, gray-scale display being realized by the combinations of the emission and non-emission of light of sub-fields. Since the need for providing a time interval at this time for set-up discharge is thus eliminated, the time of suspended emission of light between sub-fields can be reduced and the luminance of the plasma display panel can be increased.

In addition, one frame is divided into a plurality of sub-fields and the display of all scan lines by each sub-field takes the time of one frame, gray-scale display being realized by the combination of emission or non-emission of light of the sub-fields. The time of suspension of light emission between sub-fields is therefore further shortened, further increasing the luminance of the plasma display panel.

The above and other objects, features, and advantages of the present invention will become apparent from the following description based on the accompanying drawings which illustrate examples of preferred embodiments of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

First Embodiment

The first embodiment of the plasma display panel drive method of the invention is first explained using FIG. 7 .

The PDP drive method of this embodiment is a mixed scan-sustain type of drive method, and the first period of the drive sequence is composed of: a set-up discharge period, a set-up discharge erase period, a write period, a sustain discharge period, and a sustain erase period; a desired image being obtained by repeating these periods for each scan line.

In FIG. 7 , Wc 1 , Wc 2 , . . . , Wcm are pulse waveforms that are applied to scan electrodes Sc 1 , Sc 2 , . . . , Scm, respectively; and Wu 1 , Wu 2 , . . . , Wum are pulse waveforms that are applied to sustain electrodes Su 1 , Su 2 , . . . , Sum, respectively. Wd is the pulse waveform that is applied to data electrodes D 1 , D 2 , . . . , Dn; and Id 1 , Id 2 , . . . , Idn are the discharge current waveforms that flow in scan electrodes Sc 1 , Sc 2 , . . . , Scm. The configuration of the PDP is the same as that of an AC memory-type of the prior art, and explanation of this structure is therefore here omitted.

As shown in FIG. 7 , when any particular scan line is in a write period (for example, the first scan line in FIG. 7 ) in the PDP drive method of this embodiment, a set-up discharge is carried out in the next scan line to be scanned (for example, the second scan line in FIG. 7 ). To prevent the occurrence of discharge due to the set-up discharge pulse and a data pulse that is applied to data electrodes at this time, as shown in FIG. 7 , a gradually rising first set-up discharge pulse is applied to the scan electrodes of the scan line that is in the set-up discharge period, and a second set-up discharge pulse having a polarity that differs from the first set-up discharge pulse is applied to the sustain electrodes of the scan line that in the set-up discharge period.

Here, a gradually rising (having a slope lower than 5 V/ s) pulse of positive voltage is applied as the first set-up discharge pulse, and a pulse that satisfies the conditions of equations (1) and (2) below is applied as the second set-up discharge pulse.

wherein Vp 1 is the voltage of the first set-up discharge pulse, Vp 2 is the voltage of the second set-up discharge pulse, Vfsu is the voltage between the scan electrodes and sustain electrodes at the start of discharge, Vd is the voltage of data pulses that are applied to the data electrodes, and Vfud is the voltage between the sustain electrodes and the data electrodes at the start of discharge. A rectangular pulse is applied as the second set-up discharge pulse in FIG. 7 , but a waveform may also be used in which voltage changes gradually, as with the first set-up discharge pulse. For example, see signal line Wu 1 * in FIG. 7 .

In this embodiment, when any particular scan line is in a set-up discharge period and set-up discharge erase period, scan lines other than the scan line in which the immediately preceding set-up discharge was performed are in the sustain discharge period (two emissions of light).

When any particular scan line is in a set-up discharge erase period, the sustain erase period of the next scan line that is to be scanned is caused to coincide with that set-up discharge erase period, and the set-up discharge erase pulse and sustain erase pulse are applied as the same gradually falling shape. The same drive circuit can thus be shared, thereby preventing an increase in circuit scale.

In this embodiment, moreover, when any particular scan line is in a write period, the scan pulse is applied on top of a scan base pulse (a pulse having a voltage of Vbw). At this time, scan lines other than the scan line that is in the write period and the scan line that is in the set-up discharge period are in a rest period in which sustain discharge is not performed, but since the sustain electrodes in this embodiment are held at ground potential (0 V), i.,e., a higher potential than the scan electrodes, the annihilation of the wall charge that is generated by sustain discharge can be suppressed. Increase of the minimum sustain voltage necessary for sustain discharge can therefore be suppressed.

As in the prior art, data pulses are in synchronism with the application of scan pulses to scan electrodes and are applied to data electrodes corresponding to the display cells in which writing is to be performed. In addition, sustain discharge is continued by bringing about inversion of the potential of the scan electrodes and sustain electrodes from the ground potential to Vs or from Vs to the ground potential until a sustain erase pulse is applied.

The above-described scan base pulse is applied in order to lower the voltage of the scan pulse that is applied to the scan electrodes. Application of this scan base pulse enables a decrease of the maximum voltage used by the driver IC that generates scan pulses, and allows the use of a less expensive driver IC.

If the amplitude of the scan pulses is large, discharge will occur when the scan pulse is returning to higher voltage level due to the wall charge that is generated by the write discharge and the large number of active particles in the discharge space. This is an undesirable discharge that reduces the wall charges brought by the write discharge. The application of a scan base pulse, however, lowers the voltage of the scan pulses and prevents this undesirable discharge.

Explanation is next presented using FIG. 8 regarding the state of change in wall charge and the change in discharge inside display cells caused by the pulse waveforms shown in FIG. 7 . The states of change in wall charge shown in (a)-(f) in FIG. 8 correspond to periods (a)-(f) shown in FIG. 7 . The states of change of wall charge are explained below, taking as an example any display cells on the first scan line, second scan line, and m th scan line.

In FIG. 8 ( a ), when a scan pulse is applied to scan electrode Sc 1 on the first scan line and a data pulse is applied to any data electrode, discharge occurs between scan electrode Sc 1 and the data electrode, and this discharge in turn also induces discharge between scan electrode Sc 1 and sustain electrode Su 1 . At this time, positive wall charge accumulates at scan electrode Sc 1 , and a negative wall charge accumulates at the data electrode and sustain electrode Su 1 .

Meanwhile, on the second scan line, a first set-up discharge pulse is applied to scan electrode Sc 2 and a second set-up discharge pulse is applied to sustain electrode Su 2 . At this time, a weak discharge occurs between scan electrode Sc 2 and sustain electrode Su 2 , a relatively small negative wall charge accumulates at scan electrode Sc 2 , and a relatively small positive wall charge accumulates at sustain electrode Su 2 .

In FIG. 8 ( b ), upon reversal of the voltage that is applied to scan electrode Sc 1 and sustain electrode Su 1 of the first scan line, a sustain discharge is generated between scan electrode Sc 1 and sustain electrode Su 1 , a negative wall charge accumulates at scan electrode Sc 1 , and a positive wall charge accumulates at sustain electrode Su 1 .

On the second scan line, scan electrode Sc 2 becomes the ground potential and Vs is applied to sustain electrode Su 2 , but since there is no change in the relative electric potentials, the same state as FIG. 8 ( a ) is maintained.

In FIG. 8 ( c ), upon reversal of the voltage that is applied to scan electrode Sc 1 and sustain electrode Su 1 on the first scan line, sustain discharge occurs between scan electrode Sc 1 and sustain electrode Su 1 , a positive wall charge accumulates at scan electrode Sc 1 , and a negative wall charge accumulates at sustain electrode Su 1 .

Meanwhile, on the second scan line, a set-up discharge erase pulse is applied to scan electrode Sc 2 , and the wall charge that had accumulated at scan electrode Sc 2 and sustain electrode Su 3 is annihilated.

In FIG. 8 ( d ), the same state as in FIG. 8 ( c ) is maintained when scan electrode Sc 1 and sustain electrode Su 1 on the first scan line both become the ground potential because the relative electric potential does not invert.

When a scan pulse is applied to scan electrode Sc 2 on the second scan line and a data pulse is applied to a data electrode, however, discharge occurs between scan electrode Sc 2 and the data electrode, and this discharge in turn induces a discharge between scan electrode Sc 2 and sustain electrode Su 2 . At this time, a positive wall charge accumulates at scan electrode Sc 2 and a negative wall charge accumulates at the data electrode and sustain electrode Su 2 .

When scan electrode Sc 1 on the first scan line becomes the ground potential and Vs is applied to sustain electrode Su 1 in FIG. 8 ( e ), the voltages applied to scan electrode Sc 1 and sustain electrode Su 1 inverts from the state of FIG. 8 ( c ), whereby a sustain discharge occurs between scan electrode Sc 1 and sustain electrode Su 1 , a negative wall charge accumulates at scan electrode Sc 1 , and a positive wall charge accumulates at sustain electrode Su 1 .

Further, when scan electrode Sc 2 on the second scan line becomes the ground potential and Vs is applied to sustain electrode Su 2 , a sustain discharge occurs between scan electrode Sc 2 and sustain electrode Su 2 , whereupon a negative wall charge accumulates at scan electrode Sc 2 and a positive wall charge accumulates at sustain electrode Su 2 .

On the m th scan line, a set-up discharge is performed immediately before and scan electrode Scm becomes the ground potential and Vs is applied to sustain electrode Sum. Since the relative electric potential does not change from the time of the set-up discharge, however, a negative wall charge accumulates at scan electrode Scm and a positive wall charge accumulates at sustain electrode Sum.

In FIG. 8 ( f ), the application of a sustain discharge erase pulse to scan electrode Sc 1 on the first scan line brings about an erase discharge, which is a weak discharge state, and the wall charges that had accumulated at scan electrode Sc 1 and sustain electrode Su 1 are annihilated. However, the negative wall charge at the data electrode remains.

Further, when Vs is applied to scan electrode Sc 2 on the second scan line and sustain electrode Su 2 becomes the ground potential, sustain discharge occurs between scan electrode Sc 2 and sustain electrode Su 2 , whereby a positive wall charge accumulates at scan electrode Sc 2 and a negative wall charge accumulates at sustain electrode Su 2 .

A set-up discharge erase pulse is further applied to scan electrode Scm on the m th scan line, and the wall charges that had accumulated at scan electrode Scm and sustain electrode Sum are annihilated.

Combining the PDP drive method of this embodiment with the sub-field method described in the prior art makes possible PDP gray-scale display. In such a case, there is no need for periods provided exclusively for set-up discharge (refer to FIG. 5 ), as shown in FIG. 9 , and the time of suspended emission of light in one frame period can be shortened.

Therefore, the rate of sustain discharge can be raised and the luminance of the PDP can be increased. Further, a different weight is assigned to the light emission time of each sub-field in FIG. 9 , but it is also possible to assign the same weight to a plurality of sub-fields.

Referring now to FIG. 10 , the operation of the first embodiment of the PDP drive circuit of this invention is next explained. FIG. 10 shows an example of a PDP having 480 scan lines.

As in the prior art, the PDP drive circuit of this embodiment in FIG. 10 is made up of: scan electrode drive circuit 31 for applying a pulse voltage to each of scan electrodes Sc 1 , Sc 2 , . . . , Sc 480 ; sustain electrode drive circuit 32 for applying a pulse voltage to each of sustain electrodes Su 1 , Su 2 , . . . , Su 480 ; data electrode drive circuit 33 for applying a voltage according to image signals to each data electrode; and control circuit 34 for outputting control signals to each electrode drive circuit based on vertical synchronizing signals, horizontal synchronizing signals, display data signals, and clock signals.

Scan electrode drive circuit 31 includes, for example, twelve scan electrode drivers 35 1 - 35 12 of 40-bit output that are connected in parallel as drivers for selectively applying scan pulses by scan line, and scan electrode common driver 36 to which each of the scan electrode drivers is connected in common.

Sustain electrode drive circuit 32 similarly includes: for example, twelve sustain electrode drivers 37 1 - 37 12 of 40-bit output that are connected in parallel as drivers for selectively applying sustain pulses by scan line, and sustain electrode common driver 38 to which each of the sustain electrode drivers is connected in common.

Scan electrode drivers 35 1 - 35 12 and sustain electrode drivers 37 1 - 37 12 each include drive units 40 1 - 40 12 for driving each scan electrode or sustain electrode, and switches 41 1 - 41 12 for supplying various power supply voltages to drive units 40 1 - 40 12 and outputting the pulse waveforms shown in FIG. 7 . Drive units 40 1 - 40 12 are made up of 40 sets of driver FETs including p-channel FETs and n-channel FETs that are push-pull connected; and switches 41 1 - 41 12 are made up of a plurality of switch FETs that are connected to various voltage supplies (a first set-up discharge pulse voltage of Vp 1 , a second set-up discharge pulse voltage of Vp 2 ; a scan base pulse voltage of Vb 2 ; a sustain pulse voltage of Vs; and the ground potential). The switch FETs are each ON/OFF controlled by control circuit 34 such that the pulse waveforms of the drive sequence shown in FIG. 7 are output from the driver FETS.

Constant-current elements 39 1 - 39 12 are circuits for outputting a gradually rising set-up discharge erase pulse and sustain erase pulse; and constant-current element 45 1 - 45 12 are circuits for outputting a gradually rising set-up discharge pulse. In addition, scan electrode common driver 36 and sustain electrode common driver 38 are circuits for supplying Vs to the source of each p-channel FET of drive units 40 1 - 40 12 , and for making the source of each n-channel FET the ground potential.

Second Embodiment

The second embodiment of the invention is next explained with reference to the accompanying figures.

Methods for achieving gray-scale display in an AC memory-type PDP include dividing one frame into a plurality of sub-fields that are each given a time weight, and then, either displaying all sub-fields by scan line within a frame as shown in FIG. 9 , or taking the time of one frame to display all scan lines for each sub-field, as shown in FIG. 11 .

In the drive method shown in FIG. 11 , the time interval in which the emission of light is suspended between each sub-field can be made even shorter than in the drive method shown in FIG. 9 , and the number of sustain emissions can therefore be increased, thereby also increasing the luminance of the PDP.

In a sub-field method such as shown in FIG. 11 , rather than carrying out write discharge in sequence per line, the time interval of the write period is divided by the number of sub-fields, and the write timing that corresponds to each sub-field is then reserved so that each sub-field is processed.

The number of sustain light emissions are increased by inserting narrow sustain pulses only during the periods of sustain discharge, thereby enabling a further increase in the luminance of the PDP.

In this embodiment, moreover, the set-up discharge erase pulse and sustain erase pulse are made wider than in the first embodiment. For example, if the width of one scan pulse is made the same as in the first embodiment, the width of the set-up discharge pulse in this embodiment is six times that of the first embodiment. Since the rise of the set-up discharge pulse can therefore be made more gradual, the set-up discharge can be made even weaker with stability, thereby making the wall charge more amenable to control and enabling stable suppression of luminance caused by set-up discharge so as to afford an improvement in the contrast of the PDP display.

In addition, the set-up discharge erase pulse and sustain erase pulse in this embodiment are made the same shape, as in the first embodiment, this being a gradually rising pulse. As for the PDP drive circuit in this embodiment, the ON/OFF timing of each switch FET under the control of the control circuit differs from the first embodiment, but the circuit configuration is the same as in the first embodiment, and explanation is therefore here omitted.

Third Embodiment

The third embodiment of the present invention is next explained with reference to the accompanying figures.

Regarding the voltages applied to the scan electrodes and sustain electrodes, the relation between the electric potentials of the two types of electrodes may be the same as in the first embodiment or the second embodiment, and for example, a set-up discharge erase pulse or sustain erase pulse need not be applied to scan electrodes.

As shown in FIG. 13 , the PDP drive method of this embodiment is a method in which a set-up discharge erase pulse and sustain erase pulse are applied to each sustain electrode.

The pulse waveforms shown in FIG. 13 are for an example in which the drive method of this embodiment is applied to the pulse waveforms of the second embodiment shown in FIG. 12 , the drive sequence being the same as in the second embodiment. In the drive sequence of the first embodiment shown in FIG. 7 , as well, the set-up discharge erase pulse and sustain erase pulse may each be applied to sustain electrodes as in this embodiment. Further, the set-up discharge erase pulse and sustain erase pulse may be a gradually rising pulse with the same shape, as in the first embodiment.

The same effect as in the first embodiment or second embodiment can also be obtained in the PDP drive method of this embodiment, in which a set-up discharge erase pulse and a sustain erase pulse are each applied to sustain electrodes as shown in FIG. 13 .

As shown in FIG. 14 , the PDP drive circuit of this embodiment has a configuration in which the circuitry for applying set-up discharge erase pulses and sustain erase pulses, which is incorporated in the scan electrode driver in the first embodiment, is moved to the sustain electrode driver. In other words, the PDP drive circuit of this embodiment is of a configuration in which constant-current circuits 42 1 - 42 12 for applying set-up discharge erase pulses and sustain erase pulses, switch FETs 43 1 - 43 12 for ON/OFF control of these constant-current circuits 42 1 - 42 12 , and diodes 44 1 - 44 12 are each added to the switch unit of the sustain electrode driver. The configuration is otherwise the same as that of the first embodiment, and explanation is therefore here omitted. FIG. 14 shows an example of a PDP having 480 scan lines.

Fourth Embodiment

The fourth embodiment of the present invention is next explained with reference to the accompanying figures.

In this embodiment, a charge- (power-) recovering circuit for reducing power consumption is added to the PDP drive circuit shown in FIG. 10 or FIG. 14 .

The charge recovery circuit is a circuit for recovering and reusing the charge that is stored in each display cell of the PDP, generally known charge recovery circuits being a charge-storing charge recovery circuit that recovers the charge of each display cell by means of an outside charge-storing capacitor, and a self-recovering charge recovery circuit that recovers charge by means of the capacitance inherent to each display cell of the PDP.

First, a simple explanation is presented regarding the principles of operation of the charge recovery circuits.

As an example, in a case in which a structure such as shown in FIG. 15A is used as a driver circuit for driving each electrode of a PDP, the circuit shown in FIG. 15A can be represented by the equivalent circuit of FIG. 15 B. FIG. 15B shows transistors Q 1 and Q 2 shown in FIG. 15A as ON resistors R 1 and R 2 , switches S 1 and S 2 , and output capacitors C 1 and C 2 . In this type of driver circuit, the energy (C 1 C 2 Cp) V 2 is consumed each time a pulse of voltage V is applied to load capacitance Cp. This energy is consumed by the ON resistors R 1 and R 2 of the elements, or by the internal resistance of the power supply unit that supplies voltage V.

As shown in FIG. 16 and FIG. 17 , a charge-storing charge recovery circuit recovers power by using LC resonance to supply charge from an outside charge-storing capacitor Cs (Cs>>Cp) when the voltage applied to the load capacitance Cp is raised, and to return charge to charge-storing capacitor Cs from load capacitance Cp when the voltage is lowered.

As shown in FIG. 18 , a self-recovering charge recovery circuit is a structure in which inductor L, which is connected in a series with switches S 11 and S 12 and diodes D 11 and D 12 , is connected in parallel to load capacitance Cp, and as with the charge-storing type, is a method that uses LC resonance during charge recovery.

As shown in FIG. 19 , current I is supplied from the driver circuit to load capacitance Cp in the direction from point B to point A in Step 1 , and when the supply of power from the driver circuit stops in Step 2 , the charge stored in load capacitance Cp is recovered by load capacitance Cp itself by way of switch S 12 , diode D 12 , and inductor L.

Next, in Step 3 , current I is supplied from the driver circuit to load capacitance Cp in the direction from point A to point B, and when the supply of power from the driver circuit stops in Step 4 , the charge stored in load capacitance Cp is recovered in the load capacitance Cp itself by way of switch S 11 , diode D 11 , and inductor L.

Referring to FIG. 20 and FIG. 21 , explanation is next presented regarding a configuration in which the above-described charge recovery circuit is incorporated into the PDP drive circuits of this invention.

The PDP drive circuit shown in FIG. 20 is a configuration in which the self-recovering type of charge recovery circuit is added to the drive circuit of the first embodiment shown in FIG. 10 .

As shown in FIG. 20 , a PDP drive circuit of this embodiment provided with the self-recovering charge recovery circuit is a configuration in which charge recovery circuit 51 is connected between the power supply line for supplying power to scan electrodes and the power supply line for supplying power to sustain electrodes.

Charge recovery circuit 51 is made up of: diode D 21 and n-channel FET Qer 1 connected in a series to inductor L 1 ; diode D 22 and n-channel FET Qer 2 connected in a series to inductor L 2 ; and inductor L 3 having a variable inductance value. One end of inductor L 3 is connected to the cathode of diode D 22 , and the other end of inductor L 3 is connected to each of the sources of n-channel FETs Qr 1 -Qr 12 that belong to each switch unit of the scan electrode driver.

Further, as shown in FIG. 20 , the p-channel FETs of the drive unit of each scan electrode driver and sustain electrode driver are P 1 P 40 , respectively, and the n-channel FETs are N 1 -N 40 , respectively. In addition, Qe 1 -Qe 12 are switch FETs that are connected in a series to constant-current elements of the scan electrode drivers; Qpr 1 -Qpr 12 are switch FETs that are connected in a series to power supply Vp 1 for the first set-up discharge pulse; Qb 1 -Qb 12 are switch FETs that are connected in a series to power supply Vbw for the scan base pulse; Qgs 1 -Qgs 2 are switch FETs for making the sources of p-channel FETs P 1 -P 40 of each scan electrode driver the ground potential; Qw 1 -Qw 12 are switch FETs for making the sources of n-channel FETs N 1 -N 40 of each scan electrode driver the ground potential; and Qs 1 -Qs 12 are switch FETs that are connected in a series to power supply voltage Vs for sustain pulses.

Diodes Dns 1 -Dns 12 are for connecting the sources of p-channel FETs P 1 -P 40 of the scan electrode drivers to the scan electrode common driver, and diodes Dps 1 -Dps 12 are for connecting the sources of the n-channel FETs N 1 -N 40 to the scan electrode common driver.

Finally, Qgs is the p-channel FET of the scan electrode common driver for making the sources of n-channel FETs N 1 -N 40 of the scan electrode drivers the ground potential; and Qss is the n-channel FET of the scan electrode common driver for making the sources of p-channel FETs P 1 -P 40 of the scan electrode drivers Vs.

Similarly, switch FETs Qpe 1 -Qpe 12 are connected in a series to power supply Vp 2 for the second set-up discharge pulse of the sustain electrode drivers; and switch FETs Qgc 1 -Qgc 12 are for making the sources of p-channel FETs P 1 -P 40 of the sustain electrode drivers the ground potential.

Diodes Dnc 1 -Dnc 12 are for connecting the sources of p-channel FETs P 1 -P 40 of the sustain electrode drivers to the sustain electrode common driver; and diodes Dpc 1 -Dpc 12 are for connecting the sources of n-channel FETs N 1 -N 40 to the sustain electrode common driver.

Finally, Qgc is the p-channel FET of the sustain electrode common driver for making the sources of n-channel FETs N 1 -N 40 of the sustain electrode drivers the ground potential, and Qsc is the n-channel FET of the sustain electrode common driver for making the sources of p-channel FETs P 1 -P 40 of the sustain electrode drivers Vs.

The operation of the PDP drive circuit that includes the self-recovering charge recovery circuit shown in FIG. 20 is next explained.

Charge recovery is basically performed at the time of applying the sustain erase pulse and the sustain pulse.

When a sustain erase pulse is applied to the first scan line, for example, switch FET Qe 1 , which is connected to a constant current element, is turned ON, and the potential of scan electrode Sc 1 is gradually lowered at a fixed potential gradient to Vs by way of the diode that is connected in parallel to p-channel FET P 1 of the scan electrode driver.

After the potential of scan electrode Sc 1 reaches Vs, switch FET Qe 1 is turned OFF, n-channel FET Qer 1 of charge recovery circuit 51 is turned ON, and the charge stored in the display cell is recovered to the display cell itself by way of inductor L 1 , diode Dps 1 , and n-channel FET N 1 of the scan electrode driver. Operation at this time moves the potential of scan electrode Sc 1 toward the ground potential, but the potential does not actually reach the ground potential due to loss brought about by the impedance of the circuit and wiring.

After, or immediately before, charge recovery by way of inductor L 1 ends, p-channel FET Qgs of the scan electrode common driver is turned ON, and the potential of scan electrode Sc 1 is fixed at the ground potential through diode Dps 1 and n-channel FET N 1 of the scan electrode driver.

Meanwhile, the potential of sustain electrode Su 1 before the sustain erase is fixed at Vs, and n-channel FET Qsc of the sustain electrode common driver is in an ON state. Accordingly, turning OFF n-channel FET Qsc and turning ON n-channel FET Qer 2 of charge recovery circuit 51 immediately before sustain erase causes the charge stored in the display cell to be recovered by the display cell itself by way of inductor L 2 , diode Dpc 1 , and n-channel FET N 1 of the sustain electrode driver. Operation at this time causes the potential of sustain electrode Su 1 to approach the ground potential, but loss brought about by the impedance of the circuit and wiring prevents the potential from reaching the ground potential.

Either after or immediately before charge recovery ends by way of inductor L 2 , p-channel FET Qgc of the sustain electrode common driver is turned ON, and sustain electrode Su 1 is fixed at the ground potential through diode Dpc 1 and n-channel FET N 1 of the sustain electrode driver.

Subsequently, p-channel FET Qgc of the sustain electrode common driver is turned OFF immediately before the next set-up discharge period, immediately following which, switch FETs Qpe 1 and Qgc 1 of the sustain electrode driver are each turned ON.

The second set-up discharge pulse is output to sustain electrode Suk (k 1-40), which is paired with scan electrode Sck, to which the first set-up discharge pulse was applied in the set-up discharge period, and the potential of sustain electrode Suk is fixed at Vp 2 by turning ON the n-channel FET of the corresponding sustain electrode driver.

In sustain electrodes other than the sustain electrode that corresponds to the above-described n-channel FET, which is in an ON state, the paired p-channel FETS are turned ON, and the potential of these sustain electrodes is therefore fixed to the ground potential.

A sustain pulse is next applied by means of charge recovery using LC resonance to a scan electrode to which the sustain erase pulse is not applied, i.e., to a scan electrode Scj (j 1-40) to which a sustain pulse is selectively applied.

If the scan electrode to which the sustain pulse is applied is Sc 40 , for example, turning ON n-channel FET N 40 , which is connected to scan electrode Sc 40 , and switch FET Qr 1 of the corresponding scan electrode driver causes the charge that is stored in the display cell to be recovered by the display cell itself through n-channel FET N 40 , switch FET Qr 1 , and inductor L 3 .

The scan electrode driver therefore attempts to output the sustain erase pulse to scan electrode Sc 40 , but scan electrode Sc 40 is forcibly biased to Vs at a slope of (L 3 Cp) 1/2 (Cp being the load capacitance). Since the number of scan electrodes to which the sustain pulse is applied changes over time, the value of inductor L 3 can be varied or switched to keep the gradient of the rise of the sustain pulse at a uniform gradient. Inductor L 3 may also be a fixed value if the change in rise gradient of the sustain pulse due to changes in the number of scan electrodes to which sustain pulses are applied remains within a permissible range in terms of characteristics.

However, the scan electrode driver operates to fix the potential of scan electrode Sc 40 at Vs, but Vs is not attained due to loss that occurs due to the impedance of the circuit and wiring.

Nevertheless, either after or immediately before the completion of charge recovery by inductor L 3 , n-channel FET Qs 1 of the switch unit is turned ON and the potential of scan electrode Sc 40 is fixed at Vs.

After the passage of a prescribed time interval following fixing of the potential of scan electrode Sc 40 to Vs, n-channel FET N 40 , which is connected to scan electrode Sc 40 , and n-channel FET Qr 1 of the switch unit are turned OFF, and n-channel FET Qer 1 of charge recovery circuit 51 is turned ON to cause the display cell itself to recover the charge stored in the display cell through inductor L 1 , diode Dps 1 , and n-channel FET N 40 of the scan electrode driver. Operation at this time moves the potential of scan electrode Sc 40 toward the ground potential, but the ground potential is not attained due to the occurrence of loss resulting from the impedance of the circuit and wiring.

However, either after or immediately before the end of charge recovery by inductor L 1 , p-channel FET Qgs of the scan electrode common driver is turned ON, and scan electrode Sc 40 is fixed to the ground potential through diode Dps 1 and n-channel FET N 40 of the scan electrode driver.

The PDP drive circuit shown in FIG. 21 is a configuration in which a charge-storing type charge recovery circuit is added to the drive circuit of the first embodiment shown in FIG. 10 .

As shown in FIG. 21 , the drive circuit of this embodiment that has been provided with charge-storing type charge recovery circuits is a configuration in which first charge recovery circuit 61 is connected to the power supply line for supplying power to scan electrodes and second charge recovery circuit 62 is connected to the power supply line for supplying power to sustain electrodes.

First charge recovery circuit 61 is made up of: diode D 31 and n-channel FET Qns connected in a series to inductor L 11 ; diode D 32 and p-channel FET Qps connected in a series to inductor L 12 ; inductor L 13 having a variable inductance value; and first charge storing capacitor Cs that stores charge that is recovered from display cells by way of scan electrodes. One end of inductor L 13 is connected in common to the source of n-channel FET Qns and the drain of p-channel FET Qps, and the other end of inductor L 13 is connected to each of the sources of n-channel FETs Qr 1 -Qr 12 belonging to the switch units of each of the scan electrode drivers.

Second charge recovery circuit 62 is made up of: diode D 33 and p-channel FET Qpc connected in a series to inductor L 14 ; diode D 34 and n-channel FET Qnc connected in a series to inductor L 15 ; and second charge-storing capacitor Cc that stores charge that is recovered from display cells by way of sustain electrodes.

As shown in FIG. 21 , p-channel FETs P 1 -P 40 and n-channel FETs N 1 -N 40 make up the drive unit of each scan electrode driver and sustain electrode driver. In addition, switch FETs Qe 1 -Qe 12 are connected in a series to the constant-current elements of the scan electrode drivers; switch FETs Qpr 1 -Qpr 12 are connected in a series to power supply Vp 1 for the first set-up discharge pulse; switch FETs Qb 1 -Qb 12 are connected in a series to power supply Vbw for the scan base pulse; switch FETs Qgs 1 -Qgs 12 are for making the sources of p-channel FETs P 1 -P 40 of each scan electrode the ground potential; switch FETs Qw 1 -Qw 12 are for making the sources of n-channel FETs N 1 -N 40 of each scan electrode driver the ground potential; and switch FETs Qs 1 -Qs 12 are connected in a series with power supply voltage Vs for sustain pulses.

Further, diodes Dns 1 -Dns 12 connect the sources of p-channel FETs P 1 -P 40 of the scan electrode drivers to the scan electrode common driver; and diodes Dps 1 -Dps 12 connect the sources of n-channel FETs N 1 -N 40 to the scan electrode common driver.

Finally, p-channel FET Qgs of the scan electrode common driver is for making the sources of n-channel FETs N 1 -N 40 of the scan electrode drivers the ground potential; and n-channel FET Qss of the scan electrode common driver is for making the sources of p-channel FETs P 1 -P 40 of the scan electrode drivers Vs.

Similarly, switch FETs Qpe 1 -Qpe 12 are connected in a series with power supply Vp 2 for the second set-up discharge pulse of the sustain electrode drivers; and switch FETs Qcg 1 -Qgc 12 are for making the sources of p-channel FETs P 1 -P 40 of the sustain electrode drivers the ground potential.

Diodes Dnc 1 -Dnc 12 connect the sources of p-channel FETs P 1 -P 40 of the sustain electrode drivers to the sustain electrode common driver; and diodes Dpc 1 -Dpc 12 connect the sources of n-channel FETs N 1 -N 40 to the sustain electrode common driver.

Further, p-channel FET Qgc of the sustain electrode common driver is for making the sources of n-channel FETs N 1 -N 40 of the sustain electrode drivers the ground potential, and n-channel FET Qsc of the sustain electrode common driver is for making the sources of p-channel FETs P 1 -P 40 of the sustain electrode drivers voltage Vs.

The operation of the drive circuit that is provided with the charge-storing type of charge recovery circuit shown in FIG. 21 is next explained.

As with the above-described self-recovering type of charge recovery circuit, charge recovery is carried out at the time of applying sustain erase pulses and at the time of applying sustain pulses.

In a case in which a sustain erase pulse is applied to the first scan line, for example, switch FET Qe 1 , which is connected to a constant-current element, is turned ON, and scan electrode Sc 1 is gradually lowered to Vs by a fixed potential gradient through the diode that is connected in parallel to p-channel FET P 1 of the scan electrode driver.

After the potential of scan electrode Sc 1 reaches Vs, switch FET Qe 1 is turned OFF, and p-channel FET Qps of first charge recovery circuit 61 is turned ON. Since the charge that was recovered through the immediately preceding sustain discharge is stored in first charge-storing capacitor Cs at this time, operation is performed such that the charge that is stored in first charge storing capacitor Cs is supplied to the display cell by way of inductor L 12 , diode Dps 1 , and n-channel FET N 1 of the scan electrode driver; and scan electrode Sc 1 is fixed to the ground potential. However, loss occurs due to the impedance of the circuit and wiring, and the potential of scan electrode Sc 1 therefore fails to reach the ground potential by the amount of this loss.

In this regard, either after or immediately before the end of charge recovery though inductor L 12 , p-channel FET Qgs of the scan electrode common driver is turned ON to fix scan electrode Sc 1 to the ground potential through diode Dps 1 and n-channel FET N 1 of the scan electrode driver.

Before sustain erase, the potential of sustain electrode Su 1 is fixed to Vs, and n-channel FET Qsc of the sustain electrode common driver is in an ON state. Accordingly, when n-channel FET Qsc is turned OFF and p-channel FET Qpc of second charge recovery circuit 62 is turned ON immediately before sustain erase, the charge recovered through the immediately preceding sustain discharge is stored in second charge-storing capacitor Cc, and operation is therefore performed to supply the charge that was stored in first charge-storing capacitor Cs to the display cell by way of inductor L 14 , diode Dpc 1 , and n-channel FET N 1 of the sustain electrode driver, and to fix sustain electrode Su 1 to the ground potential. Since loss occurs due to the impedance of the circuit and wiring, however, the potential of sustain electrode Su 1 does not reach the ground potential.

In this regard, either after or immediately before the end of charge recovery by way of inductor L 14 , p-channel FET Qgc of the sustain electrode common driver is turned ON and sustain electrode Su 1 is fixed to the ground potential through diode Dpc 1 and n-channel FET N 1 of the sustain electrode driver.

Next, p-channel FET Qgc of the sustain electrode common driver is turned OFF immediately before the next set-up discharge period, immediately following which, switch FETs Qpe 1 and Qgc 1 of the sustain electrode driver are each turned ON.

Since the second set-up discharge pulse is to be output to sustain electrode Suk (k 1-40) which is paired with scan electrode Sck (k 1-40) to which the first set-up discharge pulse is applied in the set-up discharge period, the potential of sustain electrode Suk is fixed to Vp 2 by turning ON the n-channel FET of the corresponding sustain electrode driver.

Since the paired p-channel FETs are ON in sustain electrodes other than the sustain electrode corresponding to the above-described n-channel FET that is in an ON state, the potential of these sustain electrodes is fixed to the ground potential.

As for scan electrodes to which the sustain erase pulse is not applied, i.e., a scan electrode Scj (j 1-40) to which a sustain pulse is selectively applied, the sustain pulse is applied by means of charge recovery using LC resonance.

In a case in which Sc 40 is the scan electrode to which a sustain pulse is applied, for example, the charge that is stored in the display cell is recovered at first charge-storing capacitor Cs through n-channel FET N 40 , switch FET Qr 1 , and inductor L 13 by turning ON n-channel FET N 40 , which is connected to scan electrode Sc 40 , and switch FET Qr 1 of the corresponding scan electrode driver.

The scan electrode driver thus attempts to output a sustain erase pulse to scan electrode Sc 40 , but scan electrode Sc 40 is forcibly biased to Vs at a slope of (L 13 Cp) 1/2 (Cp being the load capacitance). Since the number of scan electrodes to which a sustain pulse is applied changes over time, the value of inductor L 13 can be either varied or switched so that the rise gradient of the sustain pulse is kept uniform.

Inductor L 13 may also have a fixed value if the variation in the rise gradient of the sustain pulse that is caused by change in the number of scan electrodes to which a sustain pulse is applied stays within a permissible range in regard to characteristics.

Operation is performed to fix the potential of scan electrode Sc 40 at Vs, but the potential does not reach Vs due to the occurrence of loss caused by impedance of the circuit and wiring.

In this regard, n-channel FET Qs 1 of the switch unit is turned ON either after or immediately before the end of charge recovery by inductor L 13 to fix the potential of scan electrode Sc 40 at Vs.

After the passage of a prescribed time period following fixing the potential of scan electrode Sc 40 at Vs, n-channel FET N 40 , which is connected to scan electrode Sc 40 , and n-channel FET Qr 1 of the switch unit are turned OFF, and n-channel FET Qps of first charge recovery circuit 61 is turned ON.

At this time, the charge that was recovered through the immediately preceding sustain discharge is stored in first charge-storing capacitor Cs, and as a result, operation is performed to supply the charge that was stored in first charge storing capacitor Cs to the display cell through inductor L 12 , diode Dps 1 , and n-channel FET N 40 of the scan electrode driver, and to fix scan electrode Sc 40 to the ground potential. The occurrence of loss due to the impedance of the circuit and wiring, however, prevents the potential of scan electrode Sc 40 from reaching the ground potential.

In this regard, p-channel FET Qgs of the scan electrode common driver is turned ON either after or immediately before the end of charge recovery by inductor L 12 to fix the potential of scan electrode Sc 40 to the ground potential through diode Dps 1 and n-channel FET N 40 of the scan electrode driver.