KR20010098117A - Apparatus for driving plasma display panel - Google Patents

Abstract

The apparatus according to the present invention comprises: address electrode lines arranged parallel to each other on a front surface of a rear substrate; And a plasma display panel including Y electrode lines and X electrode lines arranged at right angles to the address electrode lines on the rear surface of the front substrate.

The apparatus includes a control unit, an address driver, a scan driver, and an XY common driver. The controller generates driving control signals according to an image signal from the outside. The address driver processes an address signal among the drive control signals from the controller and applies the address signal to the address electrode lines. The scan driver sequentially scans the Y electrode lines according to the Y drive control signal among the drive control signals from the controller, thereby forming wall charges in the discharge cells selected according to the address signal. The XY common driver is configured to apply an AC pulse voltage between the Y electrode lines and the X electrode lines according to the Y drive control signal and the X drive control signal among the drive control signals from the control unit, so that wall charges are formed in the discharge cells. Causes display discharge at.

Description

Apparatus for driving plasma display panel

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a drive device for a plasma display panel, and more particularly, to a drive device for an AC plasma display panel of a three-electrode surface discharge method.

1 shows a configuration of a general three-electrode plasma display panel 1.

Referring to FIG. 1, between the front and rear glass substrates 10 and 13 of a typical three-electrode plasma display panel 1, the address electrode lines A _R1 , A _G1 ,..., A _Gm , A _Bm ), dielectric layers 11 and 15, Y electrode lines (Y ₁ , ... Y _n ), X electrode lines (X ₁ , ... X _n ), fluorescent layer 16, partition wall 17 ) And a magnesium monoxide (MgO) layer 12 as a protective layer.

The address electrode lines A _R1 , A _G1 ,..., A _Gm , A _Bm are formed in a predetermined pattern on the front surface of the rear glass substrate 13. The lower dielectric layer 15 is entirely formed in front of the address electrode lines A _R1 , A _G1 ,..., A _Gm , and A _Bm . The barrier ribs 17 are formed on the front surface of the lower dielectric layer 15 in a direction parallel to the address electrode lines A _R1 , A _G1 ,..., A _Gm and A _Bm . These partitions 17 function to partition the discharge area of each discharge-cell and to prevent optical cross talk between each discharge-cell. The fluorescent layer 16 is formed between the partition walls 17.

The X electrode lines X ₁ , ... X _n and the Y electrode lines Y ₁ , ... Y _n are address electrode lines A _R1 , A _G1 , ..., A _Gm , A _Bm It is formed in a predetermined pattern on the back of the front glass substrate 10 so as to be orthogonal. Each intersection defines a corresponding discharge-cell. The upper dielectric layer 11 is formed behind the X electrode lines X ₁ , ... X _n and the Y electrode lines Y ₁ , ... Y _n . A magnesium monoxide (MgO) layer 12 for protecting the panel 1 from the strong electric field is formed on the backside of the upper dielectric layer 11. The plasma forming gas is sealed in the discharge space 14.

FIG. 2 shows driving signals applied to the panel of FIG. 1.

In FIG. 2, reference numeral S _A denotes a drive signal applied to each address electrode line (A _R1 , A _G1 ,..., A _Gm , A _Bm of FIG. 1), and S _X denotes X electrode lines (FIG. 1). X ₁ , ... X _n ) driving signals applied to each other, and S _Y1 , ..., S _Yn represents driving signals applied to each Y electrode line (Y ₁ , ... Y _{n in} FIG. 1). Point. Referring to FIG. 2, the address period A1 in the unit sub-field SF1 is divided into a reset period A11, A12, A13 and a main address period A14.

In the display discharge period S1, the voltage V _S higher than the positive voltage V _XB is applied to all of the Y electrode lines Y ₁ , ... Y _n and the X electrode lines X ₁ , ... X _n . A common pulse is applied alternately, causing display discharge in the discharge-cells in which wall charges are formed in the corresponding address period A1. In this display discharge period S1, when the final pulse is applied to the X electrode lines X ₁ , ... X _n , electrons are around the X electrode of the selected and displayed discharge-cells, and a positive charge is around the Y electrode. Are formed. Accordingly, in the first reset period A11, a voltage V _RX lower than the positive voltage V _XB is applied to the X electrode lines X ₁ ,... X _n to perform a discharge for first erasing wall charges. do. Further, in the second reset period A12, a narrow pulse of voltage V _S is applied to all of the Y electrode lines Y ₁ ,... Y _n to perform a discharge for secondly erasing the remaining wall charges. . In the third reset period A13, the voltage V _RX is applied again to the X electrode lines X ₁ ,... X _n to perform a discharge for finally erasing wall charges. Accordingly, all the wall charges can be erased and the space charges can be uniformly distributed in the discharge space.

In the main address period A14, a display data signal is applied to the address electrode lines 3A _R1 , A _G1 , ..., A _Gm , A _Bm and at the same time, each Y electrode line Y ₁ , ... Y _n Are sequentially applied. The display data signal applied to each of the address electrode lines A _R1 , A _G1 , ..., A _Gm , A _Bm has a positive polarity Va when the discharge-cell is selected, and a ground voltage of 0 [otherwise. V] is applied. To each Y electrode line Y ₁ ,... Y _n , a bias voltage V _YB is applied at the time when it is not scanned, and 0 [V] is applied at the time when it is scanned. Accordingly, when the display data signal of voltage Va is applied while the scan pulse of 0 [V] is applied, wall charges are formed by the address discharge in the corresponding discharge cell, and wall charges are not formed in the discharge cell. . Here, for more accurate and efficient address discharge, the voltage V _XB which is lower than the voltage V _S and higher than V _YB is applied to the X electrode lines X ₁ ,... X _n .

3 shows a conventional driving device for generating the driving signals of FIG. 2.

Referring to FIG. 3, the conventional driving apparatus includes a control unit 2, an address driver 3, an X-common driver 4, a Y-common driver 5, and a scan driver 6. The controller 2 generates driving control signals S _CA , S _CY , and S _CX according to an image signal from the outside. The address driver 3 processes the address signal S _CA among the drive control signals S _CA , S _CY , and S _CX from the controller 2 to generate a display data signal S _{A in} FIG. 2. The generated display data signal S _A is applied to the address electrode lines A _R1 , A _G1 , ..., A _Gm and A _Bm . The X-common driving unit 4 processes the X driving control signal S _CX among the driving control signals S _CA , S _CY , S _CX from the control unit 2 to form the X electrode lines X ₁ ,. .X _n ).

The Y-common driver 5 and the scan driver 6 process the Y drive control signal S _CY among the drive control signals S _CA , S _CY , and S _CX from the control unit 2 to Y electrode lines. Applies to (Y ₁ , ... Y _n ). The scan driver 6 outputs the drive signal only in the address period (A1 in Fig. 2), and the Y-common driver 5 outputs the drive signal only in the display discharge period S1.

Meanwhile, a power regeneration circuit must be provided in the driving device of the plasma display panel with high driving power consumption. Such a power regeneration circuit is provided in the Y-common driver 5 and the X-common driver 4. That is, in the Y-common driver 5 and the X-common driver 4, in the display discharge period (S1 of FIG. 2), the display discharge pulse of the voltage V _S is applied to the X electrode lines X ₁ ,. When applied to the .X _n ) and Y electrode lines Y ₁ , ... Y _n periodically, the discharge-cells to be displayed in the next pulse period by recovering unnecessary power to the discharge-cells displayed in the current pulse period. To apply.

Referring to FIG. 4, the Y-common drive 5 of the apparatus of FIG. 3 includes a charge / discharge capacitor C _SY , four switching elements SW1,..., SW4, a tuning coil L and a current. Control diodes and the like.

Just before the sustain discharge voltage V _SY is applied to the Y electrode lines Y ₁ , ... Y _n in the sustain discharge cycle, the first switching element SW1 is turned on to charge / discharge capacitor C _SY. The electric charges collected at the C) are applied to the Y electrode lines Y ₁ ,... Y _n through the tuning coil L and the scan driver 6. In addition, when the third switch SW3 is turned off (that is, when the application of the sustain discharge voltage V _{SY is completed} ), the second switching element SW1 is turned on to turn on the plasma display panel ( Unnecessary charges are collected in each of the discharge cells C _P1 , C _P2, ..., C _Pn-1 , C _{Pn of 1} ). The fourth switching element SW4 is turned off while the sustain discharge voltage is applied to the Y electrode lines Y ₁ , ... Y _n , and the X electrode lines X ₁ , ... X _n. (ON) while the sustain discharge voltage is applied.

Referring to FIG. 5, the X-common drive 4 of the device of FIG. 3 includes a charge / discharge capacitor C _SX , four switching elements SW5,..., SW8, a tuning coil L and a current. Control diodes and the like.

Just before the sustain discharge voltage V _SX is applied to the X electrode lines X ₁ , ... X _n in the sustain discharge cycle, the fifth switching element SW5 is turned on to charge / discharge capacitor C _SX. The charges that have been collected at) are applied to the X electrode lines (X ₁ , ... X _n ) through the tuning coil (L). In addition, when the seventh switch SW7 is turned off (that is, when the application of the sustain discharge voltage V _SX is terminated), the sixth switching element SW6 is turned on and the plasma display panel ( Unnecessary charges are collected in each of the discharge cells C _P1 , C _P2, ..., C _Pn-1 , C _{Pn of 1} ). The eighth switching element SW8 is turned off while the sustain discharge voltage is applied to the X electrode lines X ₁ , ... X _n , and the Y electrode lines Y ₁ , ... Y _n. (ON) while the sustain discharge voltage is applied.

According to the conventional driving apparatus as described above, the X-common driving unit 4 and the Y-common driving unit 5 which perform only similar functions with each other in the same driving period are separated separately. As a result, expensive power recovery circuits are unnecessarily used, resulting in uneconomical problems.

SUMMARY OF THE INVENTION An object of the present invention is to provide a driving device capable of minimizing the number of expensive elements used in the X-common driving unit and the Y-common driving unit in the driving apparatus of a three-electrode surface discharge plasma display panel.

1 is an internal perspective view illustrating a configuration of a typical three-electrode plasma display panel.

FIG. 2 is a timing diagram illustrating driving signals applied to the panel of FIG. 1.

3 is a view showing a conventional driving device for generating the driving signals of FIG.

4 shows the internal circuit of the Y-common drive of the device of FIG.

5 shows the internal circuitry of the X-common drive of the device of FIG.

6 is a view showing a driving apparatus according to the present invention for generating the driving signals of FIG. 2.

FIG. 7 shows an embodiment of an XY-common drive of the apparatus of FIG. 6.

8 is a control timing diagram showing the operation of the XY-common drive of FIG.

9 shows another embodiment of the XY-common drive of the device of FIG. 6.

10 is a control timing diagram showing the operation of the XY-common drive of FIG.

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

1 ... plasma display panel, 10 ... front glass substrate,

11 dielectric layer, 12 magnesium monoxide layer,

13 ... back glass substrate, 14 ... discharge space,

16 fluorescent layers, 17 bulkheads,

X ₁ , ... X _n ... X electrode line, Y ₁ , ... Y _n ... Y electrode line,

A _R1 , A _G1 , ..., A _Gm , A _Bm ... address electrode line,

SF1 ... unit sub-field, A1 ... address cycle,

S1 ... Display discharge cycle, 7 ... XY common drive unit.

The apparatus of the present invention for achieving the above object, the address electrode lines arranged in parallel to each other on the front surface of the rear substrate; And a plasma display panel including Y electrode lines and X electrode lines arranged at right angles to the address electrode lines on the rear surface of the front substrate. The apparatus includes a control unit, an address driver, a scan driver, and an XY common driver.

The controller generates driving control signals according to an image signal from the outside. The address driver processes an address signal among driving control signals from the controller and applies the address signal to the address electrode lines. The scan driver sequentially scans the Y electrode lines according to a Y driving control signal among the driving control signals from the controller to form wall charges in the discharge cells selected according to the address signal. The XY common driver is configured to apply an AC pulse voltage between the Y electrode lines and the X electrode lines according to the Y drive control signal and the X drive control signal among the drive control signals from the controller, so that the wall charge is reduced. Display discharge is caused in the formed discharge cells.

According to the driving device of the present invention, since the sustain discharge driving of the Y electrode lines and the X electrode lines is integrally performed by the XY common driving unit, an expensive X-common driving unit and a Y-common driving unit are used. The number of devices can be minimized.

Preferably, the XY common driver includes a power regeneration circuit that collects the charges remaining in the discharge cell at the time of falling of the AC pulse and applies the charges collected at the time of rising of the AC pulse.

6 shows a drive device according to the invention for generating the drive signals of FIG. 2.

Referring to FIG. 6, an apparatus according to the present invention includes address electrode lines A _R1 , A _G1 ,..., A _Gm , A _Bm arranged parallel to each other on a front surface of a rear substrate; And the Y electrode lines Y ₁ , ... Y _n and the X electrode line aligned at right angles with the address electrode lines A _R1 , A _G1 ,..., A _Gm , A _Bm at the back side of the front substrate. A device for driving the plasma display panel 1 including the fields X ₁ , ... X _n . The apparatus includes a control unit 2, an address driver 3, a scan driver 6, and an XY common driver 7.

The controller 2 generates driving control signals S _CA , S _CY , and S _CX according to an image signal from the outside. The address driver 3 processes the address signal S _CA among the drive control signals S _CA , S _CY , and S _CX from the controller 2 to generate a display data signal S _{A in} FIG. 2. The generated display data signal S _A is applied to the address electrode lines A _R1 , A _G1 , ..., A _Gm and A _Bm . The scan driver 6 outputs the drive signal only in the address period (A1 in Fig. 2), and the Y-common driver 5 outputs the drive signal only in the display discharge period S1. That is, the scan driver 6 sequentially scans the Y electrode lines Y ₁ ,... Y _n by the Y drive control signal S _CY among the drive control signals from the controller 2, Wall charges are formed in the discharge cells selected according to the address signal S _CA.

The XY common driver 7 receives the Y electrode by the Y drive control signal S _CY and the X drive control signal S _CX among the drive control signals S _CA , S _CY , and S _CX from the control unit 2. A voltage of an alternating pulse is applied between the lines Y ₁ , ... Y _n and the X electrode lines X ₁ , ... X _n to cause display discharge in the discharge cells in which wall charge is formed. .

FIG. 7 shows an embodiment of the XY-common drive 7 of the device of FIG. 6. Referring to FIG. 7, it can be seen that an expensive power reproduction capacitor C _S is unified. 8 shows the operation of the XY-common drive of FIG. Referring to FIG. 8, the operation of the XY-common drive unit 7 of FIG. 7 will be described sequentially.

In time t1-t2, the 1st switching element SW1 and the 7th switching element SW7 are ON. Accordingly, the charges collected in the power regeneration capacitor C _S are applied to the Y electrode lines Y ₁ ,... Y _n through the tuning coil L and the scan driver 6. At time t2-t3, the third switching element SW3, the sixth switching element SW6 and the seventh switching element SW7 are in an ON state. Accordingly, the sustain discharge voltage V _SY is applied to the Y electrode lines Y ₁ , ... Y _n through the scan driver 6, and the X electrode lines X ₁ , X _n are grounded. It becomes potential. During this t2-t3 time, Y is discharged in the discharge cells in which wall charges are formed around the Y electrode among the discharge cells C _P1 , C _P2 ,..., C _Pn-1 , C _{Pn of the} plasma display panel 1. A sustain discharge, that is, a display discharge, is performed in the direction from the electrode to the X electrode.

In time t3-t4, the 2nd switching element SW2, the 6th switching element SW6, and the 7th switching element SW7 are ON. Accordingly, the wall charges remaining around the Y electrode of the discharge cells in which the sustain discharge was performed at the time t2-t3 are collected in the power regeneration capacitor C _S.

At time t7-t8, the first switching device SW1, the fourth switching device SW4 and the eighth switching device SW8 are in an ON state. Accordingly, the charges collected in the power regeneration capacitor C _S are applied to the X electrode lines X ₁ ,... X _n . At the time t8-t9, the 4th switching element SW4, the 5th switching element SW5, and the 8th switching element SW8 are ON. Accordingly, the sustain discharge voltage V _SX is applied to the X electrode lines X ₁ , ... X _n , and the Y electrode lines Y ₁ , ... Y _n become the ground potential. During this t8-t9 time, X is discharged in the discharge cells in which wall charges are formed around the X electrode among the discharge cells C _P1 , C _P2 ,..., C _Pn-1 , C _{Pn of the} plasma display panel 1. A sustain discharge, that is, a display discharge, is performed from the electrode toward the Y electrode.

In time t9-t10, the 2nd switching element SW2, the 4th switching element SW4, and the 8th switching element SW8 are ON. Accordingly, wall charges remaining around the Y electrode of the discharge cells in which the sustain discharge was performed at t8-t9 time are collected in the power regeneration capacitor C _S.

The above operation process is repeatedly performed after the time t13.

FIG. 9 shows another embodiment of the XY-common drive 7 of the device of FIG. 6. Referring to FIG. 9, it can be seen that an expensive power regeneration capacitor C _S is unified. 10 shows the operation of the XY-common drive 7 of FIG. The characteristic of the XY-common driver 7 of FIG. 9 is that the charges collected in the power regenerative capacitor C _S are transferred to the display electrode lines X ₁ , X _n, Y ₁ , ... Y _n ), and the unnecessary wall charges of the selected discharge cells are collected by the power regenerative capacitor C _S through the second tuning coil L2, thereby increasing the power regeneration efficiency. Is in. Referring to FIG. 10, the operation of the XY-common drive unit 7 of FIG. 9 will be described sequentially.

In time t1-t2, the 1st switching element SW1, the 7th switching element SW7, and the 8th switching element SW7 are ON. Accordingly, the charges collected in the power regenerative capacitor C _S are applied to the Y electrode lines Y ₁ ,... Y _n through the first tuning coil L1 and the scan driver 6. At time t2-t3, the third switching element SW3, the sixth switching element SW6, the seventh switching element SW7 and the eighth switching element SW8 are in an ON state. Accordingly, the sustain discharge voltage V _SY is applied to the Y electrode lines Y ₁ , ... Y _n through the scan driver 6, and the X electrode lines X ₁ , X _n are grounded. It becomes potential. During this t2-t3 time, Y is discharged in the discharge cells in which wall charges are formed around the Y electrode among the discharge cells C _P1 , C _P2 ,..., C _Pn-1 , C _{Pn of the} plasma display panel 1. A sustain discharge, that is, a display discharge, is performed in the direction from the electrode to the X electrode.

At time t3-t4, the second switching element SW2, the sixth switching element SW6, the seventh switching element SW7 and the eighth switching element SW8 are in an ON state. Accordingly, the wall charges remaining around the Y electrode of the discharge cells in which the sustain discharge was performed at the time t2-t3 are collected by the power regenerative capacitor C _S through the second tuning coil L2.

At times t7 to t8, the first switching element SW1, the fourth switching element SW4, the ninth switching element SW9, and the tenth switching element SW10 are in an ON state. Accordingly, the charges collected in the power regenerative capacitor C _S are applied to the X electrode lines X ₁ , X _n through the first tuning coil L1. At time t8-t9, the fourth switching element SW4, the fifth switching element SW5, the ninth switching element SW9, and the tenth switching element SW10 are in an ON state. The voltage V _SX is applied to the X electrode lines X ₁ , ... X _n , and the Y electrode lines Y ₁ , ... Y _n become the ground potential. During this t8-t9 time, X is discharged in the discharge cells in which wall charges are formed around the X electrode among the discharge cells C _P1 , C _P2 ,..., C _Pn-1 , C _{Pn of the} plasma display panel 1. A sustain discharge, that is, a display discharge, is performed from the electrode toward the Y electrode.

At times t9-t10, the second switching device SW2, the fourth switching device SW4, the ninth switching device SW9, and the tenth switching device SW10 are in an ON state. Accordingly, the wall charges remaining around the Y electrode of the discharge cells in which the sustain discharge was performed at t8-t9 time are collected by the power regenerative capacitor C _S through the second tuning coil L2.

The above operation process is repeatedly performed after the time t13.

As described above, according to the driving apparatus of the plasma display panel according to the present invention, since the sustain discharge driving to the Y electrode lines and the X electrode lines is integrally performed by the XY common driving unit, the X-common driving unit and The number of expensive elements used in the Y-common drive can be minimized.

The present invention is not limited to the above embodiments, but may be modified and improved by those skilled in the art within the spirit and scope of the invention as defined in the claims.

Claims (2)

Address electrode lines arranged parallel to each other on the front surface of the rear substrate; And a device for driving a plasma display panel including Y electrode lines and X electrode lines arranged at right angles to the address electrode lines on a rear surface of a front substrate. A controller configured to generate driving control signals according to an image signal from an external device; An address driver which processes an address signal among driving control signals from the controller and applies the address signal to the address electrode lines; A scan driver configured to sequentially scan the Y electrode lines according to a Y drive control signal among the drive control signals from the controller to form wall charges in discharge cells selected according to the address signal; And Among the driving control signals from the controller, the voltage of the AC pulse is applied between the Y electrode lines and the X electrode lines according to the Y driving control signal and the X driving control signal to display the discharge cells in the wall charges. A drive device including an XY common drive unit for causing a discharge. The method of claim 1, wherein the XY common driver, And a power regeneration circuit for collecting the charges remaining in the discharge cell at the time of falling of the AC pulse and applying the collected charges at the time of rising of the AC pulse.