JP3591766B2 - PDP drive - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a driving device for a plasma display panel (hereinafter, referred to as PDP) of a matrix display system.
[0002]
[Prior art]
As is well known, various studies have been made on a PDP as a thin flat display device, and one of them is a matrix display type PDP.
FIG. 1 is a diagram showing a configuration of a PDP driving device including such a PDP.
In FIG. 1, the PDP 1 has row electrodes Y _{1 to} Y _n and row electrodes X ₁ to X which form a row electrode pair corresponding to each row (first row to n-th row) of one screen with one pair of X and Y. _Xn are formed. Further, the column electrodes D ₁ to D ₁ to D which form column electrodes corresponding to each column (first column to m-th column) of one screen with a dielectric layer and a discharge space (not shown) interposed therebetween, orthogonal to the row electrode pairs. _Dm is formed. At this time, a discharge cell corresponding to one pixel is formed at the intersection of one row electrode pair and one column electrode.
[0003]
The address driver 2 converts the pixel data of each pixel based on the video signal into a pixel data pulse having a voltage value corresponding to the logical level, and converts the pixel data pulse for each row into the column electrodes D _{1 to} D _m. Is applied. The X-row electrode driver 3 generates a reset pulse for initializing the residual wall charge amount of each discharge cell, and a sustain discharge pulse for maintaining the discharge light emitting state of the light emitting discharge cell as described later. It applied to the row electrodes _X 1 to X _n.
[0004]
Similarly to the X-row electrode driver 3, the Y-row electrode driver 4 outputs a reset pulse for initializing the residual wall charge amount of each discharge cell and a sustain discharge pulse for maintaining the discharge light-emitting state of the light-emitting discharge cells. occurs, and applies them to the row electrodes _Y 1 to Y _n. Further, the Y row electrode driver 4 forms a priming pulse for regenerating charged particles generated in the discharge cell, and forms a charge amount corresponding to the pixel data pulse for each discharge cell, thereby forming the light emitting discharge cell or the non-light emitting discharge cell. generates a scan pulse SP for setting the light-emitting discharge cell is applied them to the row electrodes Y ₁ to Y _n.
[0005]
FIG. 2 shows a specific configuration of the X-row electrode driver 3 and the Y-row electrode driver 4 with respect to the electrode _Xj and the electrode _Yj . The electrode _{X j} is the electrode of the j-th row of the electrodes _X 1 to X _n, the electrode _{Y j} is the electrode of the j-th row of the electrodes _Y 1 to Y _n. The space between the electrodes _Xj and _Yj acts as a capacitor C0.
The X-row electrode driver 3 includes two power supplies B1 and B2. The power supply B1 outputs a voltage V _s1 (for example, 170 V), and the power supply B2 outputs a voltage V _r1 (for example, 190 V). The positive terminal of the power supply B1 is connected to the connection line 11 to the electrode _Xj via the switching element S3, and the negative terminal is grounded. A switching element S4 is connected between the connection line 11 and the ground, and a series circuit including a switching element S1, a diode D1, and a coil L1, and a series circuit including a coil L2, a diode D2, and a switching element S2. The capacitor C1 is commonly connected to the ground side. The diode D1 is connected to the capacitor C1 side as an anode, and the diode D2 is connected to the capacitor C1 side as a cathode. The positive terminal of the power supply B2 is connected to the connection line 11 via the switching element S8 and the resistor R1, and the negative terminal of the power supply B2 is grounded.
[0006]
The Y row electrode driver 4 includes four power supplies B3 to B6. The power supply B3 outputs a voltage V _s1 (for example, 170V), the power supply B4 outputs a voltage V _r1 (for example, 190V), the power supply B5 outputs a voltage V _off (for example, 140V), and the power supply B6 outputs a voltage V _h (for _{example, 160V, V h> V off} ) to output. The positive terminal of the power supply B3 is connected to the connection line 12 to the switching element S15 via the switching element S13, and the negative terminal is grounded. Another switching element S14 is connected between the connection line 12 and the ground, a series circuit formed of a switching element S11, a diode D3 and a coil L 3, a series circuit consisting of a coil L4, a diode D4 and a switching element S12 Are commonly connected to the capacitor C2 on the ground side. The diode D3 is connected with the capacitor C2 side as an anode, and the diode D4 is connected with the capacitor C2 side as a cathode.
[0007]
The connection line 12 is connected to the connection line 13 to the positive terminal of the power supply B6 via the switching element S15. The positive terminal of the power supply B4 is grounded, and the negative terminal is connected to the connection line 13 via the switching element S16 and the resistor R2. The positive terminal of the power supply B5 is connected to the connection line 13 via the switching element S17, and the negative terminal is grounded.
[0008]
The connection line 13 is connected to the connection line 14 to the electrode _Yj via the switching element S21. The negative terminal of the power supply B6 is connected to the connection line 14 via the switching element S22. A diode D5 is connected between the connection lines 13 and 14, and a series circuit of the switching element S23 and the diode D6 is connected. The diode D5 is connected with the connection line 14 side as an anode, and the diode D6 is connected with the connection line 14 side as a cathode.
[0009]
The on / off of the switching elements S1 to S4, S8, S11 to S17, and S21 to S23 is controlled by a control circuit (not shown). The arrow of each switching element in FIG. 2 is a control signal terminal from the control circuit. In the Y-row electrode driver 4, the power supply B3, the switching elements S11 to S15, the coils L3 and L4, the diodes D3 and D4, and the capacitor C2 constitute a sustain driver section, and the power supply B4, the resistor R2 and the switching element S16 constitute a reset driver section. And the remaining power supplies B5, B6, the switching elements S23 , S17, S21, S22 and the diodes D5, D6 constitute a scan driver unit.
[0010]
Next, the operation of the PDP driving device having such a configuration will be described with reference to the timing chart of FIG . The operation of the PDP driving device includes a reset period, an address period, and a sustain period. First, in the reset period, the switching element S23 of the Y row electrode driver 4 is turned on. The switching element S23 is turned on during the reset period and the sustain period. At the same time, the switching element S8 of the X-row electrode driver 3 turns on, and the switching element S16 of the Y-row electrode driver 4 turns on. Other switching elements are off. Switching element (S8) from the positive terminal of the power source B2 by turning on the switching element S8, via a resistor R1 current flows in the electrodes X _j, also the electrode Y _j from the diode D5 by turning on the switching element S16, the resistor R2, a switching element S16 The current flows into the negative terminal of the power supply B4 via the power supply. Gradually rises and the reset pulse RP _x becomes the time constant of the potential of the electrode X _j and the capacitor C0 and the resistor R1, the reset potential of the electrode Y _j gradually decreases by the time constant of the capacitor C0 and the resistor R2 pulse RP _y . The reset pulse RP _x is simultaneously applied to all the electrodes X ₁ to X _n, is applied a reset pulse RP _y even electrodes Y ₁ to Y _n generated for each the electrode Y ₁ to Y _n all at once.
[0011]
The simultaneous application of these reset pulses RP _x and RP _y, all the discharge cells of PDP1 is discharged excited charged particles are generated, after the discharge termination, of all the discharge cells dielectric layer uniformly in a predetermined amount to Wall charges are formed. After the switching element S8 and a switching element S16, the level of the reset pulse RP _x and RP _y is saturated, turned off in the reset period before the end. At this time, the switching elements S4, S14 and S15 are turned on, and the electrodes _Xj and _Yj are both grounded. Thus the reset pulse RP _x and RP _y disappears.
[0012]
Next, when the address period starts, the switching elements S14 and S15 are turned off, the switching element S23 is turned off, the switching element S17 is turned on, and at the same time, the switching element S22 is turned on. When the switching element S17 is turned on, the power supply B5 and the power supply B6 are connected in series, and a negative potential indicating the difference between the voltages _Vh and _Voff is generated at the negative terminal of the power supply B6, which is applied to the electrode _Yj . Applied.
[0013]
The pixel data for each pixel address driver 2 based on the video signal in the address period, and converts the pixel data pulses DP ₁ to DP _n having a voltage value corresponding to the logical level, which for each row, the sequentially applies the column electrodes _D 1 to D _m. As shown in FIG. 3, pixel data pulses DP _j and DP _{j + 1} are applied to the electrodes Y _j and Y _{j + 1} .
[0014]
The Y row electrode driver 4 sequentially applies a positive voltage priming pulse PP to the row electrodes Y _{1 to} Y _n . Furthermore, sequentially applies the scan pulse SP of each priming pulse PP has just applied and the pixel data pulse groups DP ₁ to DP _n each of the negative voltage in synchronization with the timing to the row electrodes Y ₁ to Y _n.
Describing the electrode _Yj , when generating the priming pulse PP, the switching element S21 is turned on and the switching element S22 is turned off. Further, the switching element S17 remains on. Thereby, the potential _Voff of the positive terminal of the power supply B5 is applied as the priming pulse PP to the electrode _Yj via the switching element S17 and the switching element S21. After the application of the priming pulse PP, the switching element S21 is turned off in synchronization with the application of the pixel data pulse DP _j from the address driver 2, the switching element S22 is turned on. As a result, a negative potential indicating the difference between the voltage _Vh and _{Voff at} the negative terminal of the power supply B6 is applied to the electrode _Yj as a scanning pulse SP. Then, switching element S21 is turned on in synchronization with the stop of the application of the pixel data pulse DP _j from the address driver 2, the switching element S22 is turned off, the potential V _off switching element S17 in the positive terminal of the power source B5 and switching, The voltage is applied to the electrode _Yj via the element S21. Thereafter, as shown in FIG. 3, a priming pulse PP is applied to the electrode Y _{j + 1} similarly to the electrode Y _j, and a scan pulse SP is applied in synchronization with the application of the pixel data pulse DP _{j + 1} from the address driver 2. .
[0015]
Among the discharge cells belonging to the row electrodes to which the scan pulse SP has been applied, discharge occurs in the discharge cells to which the pixel data pulse of the positive voltage is further applied at the same time, and most of the wall charges are lost. On the other hand, no discharge occurs in the discharge cells to which the scan pulse SP is applied but the positive voltage pixel data pulse is not applied, so that the wall charges remain. At this time, the discharge cells in which the wall charge remains remain light emitting discharge cells, and the discharge cells in which the wall charge has disappeared become non-light emitting discharge cells.
[0016]
When switching from the address period to the sustain period, the switching elements S17 and S21 are turned off, and the switching elements S14 and S15 are turned on instead. The ON state of the switching element S4 is continued.
In the sustain period, in the X-row electrode driver 3, the potential of the electrode _Xj becomes the ground potential of almost 0 V by turning on the switching element S4. Next, when the switching element S4 is turned off and the switching element S1 is turned on, the electric charge stored in the capacitor C1 causes a current to reach the electrode _Xj via the coil L1, the diode D1, and the switching element S1, and the capacitor C0 To charge the capacitor C0. At this time, the potential of the electrode _Xj gradually increases as shown in FIG. 3 due to the time constant of the coil L1 and the capacitor C0.
[0017]
Next, the switching element S1 is turned off and the switching element S3 is turned on. Thus, the potential V _S1 of the positive terminal of the power supply B1 is applied to the electrode _Xj . Thereafter, the switching element S3 is turned off, the switching element S2 is turned on, and the electric charge accumulated in the capacitor C0 causes a current to flow from the electrode _Xj to the capacitor C1 via the coil L2, the diode D2, and the switching element S2. At this time, the potential of the electrode _Xj gradually decreases as shown in FIG. 3 due to the time constant of the coil L2 and the capacitor C1. When the potential of the electrode _Xj reaches almost 0 V, the switching element S2 turns off and the switching element S4 turns on.
[0018]
X row electrode driver 3 by such operation applying the sustain pulses IP _x of the positive voltage such as shown in FIG. 3 to the electrode X _j. Sustain discharge pulse IP _x is simultaneously when the switching element S4 to disappear, Y row electrode driver 4, the switching element S11 is turned on, the switching element S14 is turned off. When the switching element S14 is on, the potential of the electrode _Yj is at a ground potential of almost 0 V. However, when the switching element S14 is off and the switching element S11 is on, the electric charge stored in the capacitor C2 causes The current reaches the electrode _Yj via the coil L3, the diode D3, the switching element S11, the switching element S15, the switching element S23 , and the diode D6, flows into the capacitor C0, and charges the capacitor C0. At this time, the potential of the electrode _Yj gradually increases as shown in FIG. 3 due to the time constant of the coil L3 and the capacitor C0.
[0019]
Next, the switching element S11 is turned off, and the switching element S13 is turned on. Thus, the electrode _{Y j} potentials _{V S1} of the positive terminal of the power source B3 is applied. Thereafter, the switching element S13 is turned off, the switching element S12 is turned on, and the electric charge accumulated in the capacitor C0 causes the electrode _Yj to pass through the diode D5, the switching element S15, the coil L4, the diode D4, and the capacitor C2 via the switching element S12. The current flows into. At this time, the potential of the electrode _Yj gradually decreases as shown in FIG. 3 due to the time constant of the coil L4 and the capacitor C2. When the potential of the electrode _Yj reaches almost 0 V, the switching element S12 turns off and the switching element S14 turns on.
[0020]
Y row electrode driver 4 by such operation applying the sustain pulse IP _y of positive voltage such as shown in FIG. 3 to the electrode Y _j.
Thus, in the sustain period, since the sustain discharge pulse IP _x and sustain discharge pulse IP _y is alternately applied to the generated electrode _X 1 and to X _n and the electrodes _Y 1 to Y _n are alternately above The light emitting discharge cell in which the wall charge remains remains repeating the discharge light emission and maintains the light emitting state.
[0021]
[Problems to be solved by the invention]
In the above-described conventional PDP driving device, the scan driver unit uses a PMOS-FET or an NMOS as the switching element S21, uses an NMOS-FET as the switching element S22, and connects their connection points to the electrode _Yj by series connection. Although the output is configured as an output, in this case, since the ON resistance of the FET constituting the switching element S21 is high, the driving capability thereof is significantly inferior to that of the FET constituting the switching element S22. Therefore, the sustain discharge pulse current from the sustain driver cannot be supplied to the electrode _Yj via the switching element S21 during the sustain period, and the sustain discharge pulse current is supplied to the PDP electrode _Yj via the bypass circuit including the switching element S23 . Since the supply is performed, there is a problem that the circuit scale is increased and the cost is increased.
[0022]
Therefore, an object of the present invention is to provide a PDP driving device capable of supplying a sustain discharge pulse current to a PDP during a sustain period without increasing the circuit scale.
[0023]
[Means for Solving the Problems]
The PDP driving apparatus according to the present invention drives a plasma display panel having a plurality of row electrode pairs and a plurality of column electrodes arranged to intersect the row electrode pairs and form a discharge cell at each intersection. A scan driver that supplies a scan pulse to one of the row electrode pairs to select a light emitting cell and a non-light emitting cell; and a sustain discharge pulse to one of the row electrode pairs to maintain light emission only in the light emitting cells. A scan driver, the scan driver having a first and a second switching element each having one end commonly connected to one of the row electrode pairs; a first diode connected in parallel to the first switching element; and a second diode and the first diode connected in parallel with the second switching element so as to be opposite polarity to one row electrode pair, during the operation of the scan driver The first potential is applied to the other end of the first switching element, the second potential equal to the potential of the lower scanning pulse than the first potential is applied to the other end of the second switching element, the sustain discharge during operation of the sustain driver The output of the driver is electrically connected to the other end of the second switching element , a current is supplied from the sustain discharge driver to one of the row electrode pairs through the second diode, and the current is accumulated in the row electrode pair by the current supply. The second switching element is turned on when the charge is recovered as a current to the sustain discharge driver, whereby a sustain discharge pulse is supplied to one of the row electrode pairs .
[0025]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 4 shows a configuration of a PDP driving device according to the present invention, and the same parts as those of the conventional device shown in FIGS. 1 and 2 are denoted by the same reference numerals. In the PDP driving device shown in FIG. 4, the negative terminal of the power supply B6 is connected to the connection line 13 connected to the switching element S15. The positive terminal of the power supply B6 is connected to the connection line 14 to the electrode _Yj via the switching element S21, and the negative terminal of the power supply B6 connected to the connection line 13 is connected to the connection line 14 via the switching element S22. I have. A diode D5 is connected in parallel to the switching element S21, and a diode D6 is connected in parallel to the switching element S22. The diode D5 is connected with the connection line 14 side as an anode, and the diode D6 is connected with the connection line 14 side as a cathode.
[0026]
The power supply B5 is connected to the conventional device of FIG. 2 with the positive and negative terminals reversed, and generates, for example, 10 to 20 V as the voltage _Voff .
Other configurations are the same as those of the conventional device shown in FIGS. 1 and 2, and the description is omitted here.
Next, the operation of the PDP driving device according to the present invention having such a configuration will be described with reference to the timing chart of FIG. The operation of the PDP driving device includes a reset period, an address period, and a sustain period, as in the conventional device of FIG.
[0027]
First, in the reset period, the switching element S8 of the X-row electrode driver 3 is turned on, and both the switching elements S16 and S22 of the Y-row electrode driver 4 are turned on. Other switching elements are off. When the switching element S8 is turned on, a current flows from the positive terminal of the power source B2 to the electrode _Xj via the switching element 8 and the resistor R1, and when the switching elements S16 and S22 are turned on, the switching element S22, the resistor R2, and the switching are performed from the electrode _Yj. A current flows into the negative terminal of the power supply B4 via the element S16. Gradually rises and the reset pulse RP _x becomes the time constant of the potential of the electrode X _j and the capacitor C0 and the resistor R1, the reset potential of the electrode Y _j gradually decreases by the time constant of the capacitor C0 and the resistor R2 pulse RP _y . The reset pulse RP _x is finally voltage _{V r1,} and the reset pulse RP _y is the final voltage _{-V r1.} The reset pulse RP _x is simultaneously applied to all the electrodes _X 1 to X _n, is applied a reset pulse RP _y even electrodes _Y 1 to Y _n generated for each the electrode _Y 1 to Y _n all at once.
[0028]
The simultaneous application of these reset pulses RP _x and RP _y, all the discharge cells of PDP1 is discharged excited charged particles are generated, after the discharge termination, of all the discharge cells dielectric layer uniformly in a predetermined amount to Wall charges are formed. After the switching element S8, S16, S22 is the level of the reset pulse RP _x and RP _y is saturated, turned off in the reset period before the end. At this time, the switching elements S4, S14 and S15 are turned on, and the electrodes _Xj and _Yj are both grounded. Thus the reset pulse RP _x and RP _y disappears.
[0029]
Next, when the address period starts, the switching elements S14 and S15 are turned off, the switching element S17 is turned on, and at the same time, the switching element S22 is turned on. When the switching elements S17 and S22 are turned on, the negative potential −V _off of the negative terminal of the power supply B5 is applied to the electrode _Yj via the switching element S17 and the switching element S22.
[0030]
The pixel data for each pixel address driver 2 based on the video signal in the address period, and converts the pixel data pulses DP ₁ to DP _n having a voltage value corresponding to the logical level, which for each row, the sequentially applies the column electrodes _D 1 to D _m. As shown in FIG. 5, pixel data pulses DP _j and DP _{j + 1} are applied to the electrodes Y _j and Y _{j + 1} .
[0031]
The Y row electrode driver 4 sequentially applies a positive voltage priming pulse PP to the row electrodes Y _{1 to} Y _n . Furthermore, sequentially applies the scan pulse SP of each priming pulse PP has just applied and the pixel data pulse groups DP ₁ to DP _n each of the negative voltage in synchronization with the timing to the row electrodes Y ₁ to Y _n.
Describing the electrode _Yj , when generating the priming pulse PP, the switching element S21 is turned on and the switching element S22 is turned off. Further, the switching element S17 remains on. Since the state of being connected in series via a switching element S17, and thereby the power source B6 and supply B5, the potential of the positive terminal of the power source B6 is the _V h _{-V off} (e.g., 140 V). This positive potential is applied as a priming pulse PP to the electrode _Yj via the switching element S21.
[0032]
After the application of the priming pulse PP, the switching element S21 is turned off in synchronization with the application of the pixel data pulse DP _j from the address driver 2, the switching element S22 is turned on. As a result, the negative potential −V _off of the negative terminal of the power supply B5 is applied as a scan pulse SP to the electrode _Yj via the switching element S17 and the switching element S22. Then, switching element S21 is turned on in synchronization with the stop of the application of the pixel data pulse DP _j from the address driver 2, the switching element S22 is turned off, the positive terminal potential _V h _{-V off} switching elements S21 of the power source B6 _Is applied to the electrode _Yj . After that, as shown in FIG. 5, a priming pulse PP is applied to the electrode Y _{j + 1} similarly to the electrode Y _j, and a scan pulse SP is applied in synchronization with the application of the pixel data pulse DP _{j + 1} from the address driver 2. .
[0033]
Among the discharge cells belonging to the row electrodes to which the scan pulse SP has been applied, discharge occurs in the discharge cells to which the pixel data pulse of the positive voltage is further applied at the same time, and most of the wall charges are lost. On the other hand, no discharge occurs in the discharge cells to which the scan pulse SP is applied but the positive voltage pixel data pulse is not applied, so that the wall charges remain. At this time, the discharge cells in which the wall charge remains remain light emitting discharge cells, and the discharge cells in which the wall charge has disappeared become non-light emitting discharge cells.
[0034]
When switching from the address period to the sustain period, the switching elements S17 and S21 are turned off, and the switching elements S14 and S15 are turned on instead. The ON state of the switching element S4 is continued.
The operation of the X-row electrode driver 3 during the sustain period is the same as that of the conventional device shown in FIG. 2, and therefore the description of the operation is omitted, but the X-row electrode driver 3 maintains the positive voltage as shown in FIG. the discharge pulse IP _x applied to the electrodes _{X j.}
[0035]
In the Y-row electrode driver 4, simultaneously when the switching element S4 where the sustain pulse IP _x is extinguished, the switching element S11 is turned on, the switching element S14 is turned off. When the switching element S14 is on, the potential of the electrode _Yj is at a ground potential of almost 0 V. However, when the switching element S14 is turned off and the switching element S11 is turned on, the electric charge stored in the capacitor C2 causes The current reaches the electrode _Yj via the coil L3, the diode D3, the switching element S11, the switching element S15, and the diode D6, flows into the capacitor C0, and charges the capacitor C0. At this time, the potential of the electrode _Yj gradually rises as shown in FIG. 5 due to the time constant of the coil L3 and the capacitor C0.
[0036]
Next, the switching element S11 is turned off, and the switching element S13 is turned on. Thus, the potential _{V S1} of the positive terminal of the power source B3 to the electrode _{Y j} is applied via the switching element S13, switching element S15 and the diode D6,. Thereafter, the switching element S13 is turned off, the switching element S12 is turned on, further switching element S22 is turned on, the switching device S22 from the electrode _{Y j} by the charge accumulated in the capacitor C0, a switching element S15, the coil L4, the diode D4, Then, a current flows into the capacitor C2 via the switching element S12. At this time, the potential of the electrode _Yj gradually decreases as shown in FIG. 5 due to the time constant of the coil L4 and the capacitor C2. When the potential of the electrode _Yj reaches almost 0 V, the switching elements S12 and S22 are turned off, and the switching element S14 is turned on.
[0037]
Y row electrode driver 4 by such operation applying the sustain pulse IP _y of positive voltage such as shown in FIG. 5 to the electrode Y _j.
Thus, in the sustain period, since the sustain discharge pulse IP _x and sustain discharge pulse IP _y is alternately applied to the generated electrode _X 1 and to X _n and the electrodes _Y 1 to Y _n are alternately above The light emitting discharge cell in which the wall charge remains remains repeating the discharge light emission and maintains the light emitting state.
[0038]
【The invention's effect】
As described above, according to the present invention, the sustain discharge pulse current can be supplied to the PDP during the sustain period without passing through the bypass circuit including the switching element, so that an increase in circuit scale can be prevented.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a PDP driving device.
FIG. 2 is a circuit diagram showing a configuration of a conventional driving device.
FIG. 3 is a time chart of each part of the apparatus of FIG. 2;
FIG. 4 is a circuit diagram showing an embodiment of the present invention.
FIG. 5 is a time chart of each part of the apparatus of FIG. 4;
[Explanation of symbols]
1 PDP
2 Address driver 3 X row electrode driver 4 Y row electrode driver

Claims (3)

A driving apparatus for driving a plasma display panel having a plurality of row electrode pairs and a plurality of column electrodes arranged to intersect with the row electrode pairs and form discharge cells at each intersection, comprising: a light emitting cell; A scan driver that supplies a scan pulse to one of the row electrode pairs to select a non-light emitting cell, and a sustain discharge that supplies a sustain discharge pulse to one of the row electrode pairs to maintain light emission only in the light emitting cells. With a driver,
The scan driver includes first and second switching elements each having one end commonly connected to one of the row electrode pairs, a first diode connected in parallel to the first switching element, and one of the row electrode pairs. A second diode connected in parallel to the second switching element so as to have a polarity opposite to that of the first diode, and a first potential connected to the other end of the first switching element when the scan driver operates. Is applied, and a second potential lower than the first potential and equal to the potential of the scan pulse is applied to the other end of the second switching element .
When the sustain discharge driver is activated, an output of the sustain discharge driver is electrically connected to the other end of the second switching element , and a current is supplied from the sustain discharge driver to one of the row electrode pairs via the second diode. And the second switching element is turned on when the electric charge stored in the row electrode pair is recovered as a current to the sustain discharge driver by the current supply, whereby the sustain discharge pulse is supplied to one of the row electrode pairs. the plasma display panel driving apparatus characterized by but is supplied. The scan driver, wherein the P-channel MOS transistor of the first switching element, a plasma display panel driving apparatus according to claim 1, characterized in that it comprises an N-channel MOS transistor as the second switching element.   A third switching element different from the first and second switching elements is provided between the sustain discharge driver and one of the row electrodes, and the sustain discharge driver supplies the sustain discharge pulse to one of the row electrode pairs from the sustain discharge driver When the third switching element is turned on, the sustain discharge pulse is applied to one of the row electrodes, and the electric charge supplied from the sustain discharge driver to one of the row electrode pairs is supplied to the sustain discharge driver. 2. The electric charge supplied to one of the row electrode pairs is collected by the sustain discharge driver by turning on the second switching element and the third switching element at the time of collection. 3. The plasma display panel driving device as described in the above.

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