KR100884789B1 - Method and apparatus for driving electro-luminescence display panel wherein preliminary charging is individually performed - Google Patents

Abstract

The present invention relates to an electroluminescent display panel in which data electrode lines and scan electrode lines are formed to cross each other at predetermined intervals so that electroluminescent display cells are formed at their intersection regions, at the beginning of each horizontal driving period, Data signals to be applied to each data electrode line are cut off, a first potential is applied to the scan electrode line to be scanned, a second potential higher than the first potential is applied to all other scan electrode lines, and each data electrode A method and apparatus for driving an electroluminescent display panel performing preliminary charging steps in which lines are electrically connected to each other by switching. Here, the execution time of the preliminary charging step is changed for each data electrode line in inverse proportion to the magnitude of each data signal.

Description

Method and apparatus for driving electro-luminescence display panel wherein preliminary charging is individually performed

1 is a view showing the configuration of a conventional electroluminescent display device.

FIG. 2 is a timing diagram illustrating a method of conventionally driving the electroluminescent display panel of FIG. 1.

3 is a timing diagram showing in detail a method of driving the electroluminescent display panel of FIG. 1 in detail.

4 is a detailed timing diagram illustrating in detail a method of driving the electroluminescent display panel of FIG. 1 according to an exemplary embodiment of the present invention.

5 is a circuit diagram illustrating an internal configuration of a data driver of a driving device of an electroluminescent display panel according to the present invention.

6 is a circuit diagram showing an internal configuration of charge switches and a pulse generating circuit of a driving device of an electroluminescent display panel according to the present invention.

FIG. 7 is a circuit diagram illustrating in detail the pulse generating circuit of FIG. 6.

8 is a flowchart illustrating a preliminary charging algorithm of a controller of a driving device of an electroluminescent display panel according to the present invention.                 

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

1 electroluminescent element, 2 electroluminescent display panel,

3 ... data electrode lines, 4 ... scan electrode lines,

5 ... data drive, 6 ... scan drive,

8 ... current sources, 10a, ..., 10c ... scanning switches,

21 ... control section, 22 ... charging voltage determining section.

25 ... charge switches, 26 ... pulse generator circuit,

26a, ..., 26d ... pulse generators.

The present invention relates to a method and apparatus for driving an electroluminescent display panel, and more particularly, the data electrode lines and the scan electrode lines are formed to cross each other at a predetermined interval so that the electroluminescent display cells are intersected at the intersection regions. A method and apparatus for driving an electroluminescent display panel formed.

Referring to FIG. 1, a conventional electroluminescent display device includes an electroluminescent display panel 2 and a drive device. The driving device includes a control unit 21, a scan driver 6, and a data driver 5. Here, the charge switches 25 and the charge voltage determiner 22 may be included in the electroluminescent display panel 2 or may be included in the driving device.                         

In the electroluminescent display panel 2, the data electrode lines 3 and the scan electrode lines 4 are formed to cross each other at a predetermined interval so that the electroluminescent display cells 1 are formed in the crossing regions.

The controller 21 processes the input image signal, inputs a display data signal and a switching control signal to the data driver 5, and inputs a switching control signal to the scan driver 6 and the charge switches 25. The scan driver 6 operates in accordance with a switching control signal from the controller 21 to drive the scan electrode lines 4. The data driver 5 operating according to the switching control signal from the controller 21 drives the data electrode lines 3 according to the display data signal from the controller 21.

The charging switches 25 operate according to a switching control signal from the controller 21 to electrically connect or disconnect all the data electrode lines 3 from each other. The charge voltage determination unit 22 including the parallel circuit of the capacitor 24 and the zener diode 23 determines the preliminary charge voltage of the data electrode lines 3 as a breakdown voltage of the zener diode 23. .

1 and 2, a method of driving the electroluminescent display panel 2 in general, for example, a driving method of US Publication No. 36605 in 2002 is as follows. In FIG. 2, reference numeral S _PC denotes a preliminary charging signal input from the controller 21 to the data driver 5, the scan driver 6, and the charge switches 25. Reference numeral S _Sn denotes a scan drive signal applied from the scan driver 6 to the nth scan electrode line 4a or 4b. Reference numeral S _{Sn + 1} denotes a scan drive signal applied from the scan driver 6 to the n + 1th scan electrode line 4b or 4c. Reference numeral V _{Dn + 1} indicates a voltage waveform applied to either data electrode line.

Each horizontal drive time a, b includes a preliminary charging step (c) and scanning steps t2 to t3 and t4 to t5.

In the preliminary charging steps t1 to t2 of the nth horizontal driving time a, data signals applied to all data electrode lines 3 are blocked. In addition, by the operation of the scan switches 10a,..., And 10c, a first potential is applied to all scan electrode lines other than the nth scan electrode line, and the first potential is applied to the nth scan electrode line. A ground potential as a low second potential is applied. In addition, all data electrode lines 3 are electrically connected to each other by the operation of the charge switches 25. Accordingly, the parasitic capacitors of the electroluminescent cells 1 of the n−1 th scan electrode line that were emitted at the scan time of the previous horizontal driving time are discharged, thereby causing the parasitic capacitors of all other electroluminescent cells 1 to be discharged. Are charged, the potential of all data electrode lines rises uniformly.

In the scanning steps t2 to t3 of the nth horizontal driving time a, all data electrode lines 3 are electrically separated from each other by the operation of the charging switches 25, and the display data signals are separated from the data electrode lines. Is applied to the light emitting device 3, and the selected electroluminescent display cells of the nth scan electrode line emit light. Here, since the potentials of all the data electrode lines are uniformly raised due to the preliminary charging steps t1 to t2, a voltage may be applied to the selected electroluminescent display cells faster to increase driving speed and image quality.

The same operation principle applies to the n + 1th horizontal driving time b.

1 and 3, a method of driving the electroluminescent display panel 2 of FIG. 1 will be described in detail as follows. In FIG. 3, reference numerals S _3a to S _3e exemplarily show signals applied to the respective data electrode lines 3a to 3e. Reference numeral S _Sn denotes a scan drive signal applied from the scan driver 6 to the nth scan electrode line 4a or 4b. Reference numeral S _{Sn + 1} denotes a scan drive signal applied from the scan driver 6 to the n + 1th scan electrode line 4b or 4c. Reference numerals S _25a to S _25e denote control signals that are equally applied to the respective charge switches 25a to 25e.

Each horizontal drive time a, b includes a preliminary charging step (c) and scanning steps t2 to t3 and t4 to t5. Here, the preliminary charging step (c) is always performed for a certain time for all the data electrode lines 3, regardless of the magnitude of each data signal in the subsequent scanning steps t2 to t3 and t4 to t5. .

In the preliminary charging steps t1 to t2 of the nth horizontal driving time a, data signals applied to all data electrode lines 3 are blocked. Further, by the operation of the scan switches 10a, ..., 10c, the ground potential as the first potential is applied to the nth scan electrode line to be scanned, and to all other scan electrode lines other than the nth scan electrode line. A second potential higher than the first potential is applied. In addition, all the data electrode lines 3 are electrically connected to each other by the charging switches 25 being uniformly turned on. Accordingly, since the parasitic capacitors of the electroluminescent cells 1 of the n-th scan electrode line that were emitted at the scan time of the previous horizontal driving time are discharged, the potential set by the charging voltage determiner 22 is discharged. This makes the potential of all data electrode lines uniform.

In the scanning steps t2 to t3 of the nth horizontal driving time a, all data electrode lines 3 are electrically separated from each other by the operation of the charging switches 25, and the display data signals are separated from the data electrode lines. Is applied to the light emitting device 3, and the selected electroluminescent display cells of the nth scan electrode line emit light. Here, since the potentials of all the data electrode lines are higher than the ground potentials due to the preliminary charging steps t1 to t2, voltage may be applied to the selected electroluminescent display cells more quickly, thereby increasing luminance.

The same operation principle applies to the n + 1th horizontal driving time b.

According to the driving method of the conventional electroluminescent display panel as described above, when the nth electroluminescent cell of any data electrode line is selected in the nth horizontal driving time (a), the n + 1th horizontal driving time (b) In the preliminary charging steps t3 to t4 of the n + 1 horizontal driving time b, the n + 1 electroluminescent cell is returned even though the n + 1 electroluminescent cell of the data electrode line is not selected at. A phenomenon causing discharge, that is, a phenomenon of crosstalk through the data electrode line may occur. This is because a relatively high forward voltage is applied to the n + 1 electroluminescent cell in the preliminary charging steps t3 to t4 of the n + 1th horizontal driving time b.

In this case, as the preliminary charging period c is shorter, a relatively large current flows through the data electrode line, so that the crosstalk may occur frequently. However, as the preliminary charging period c is shorter, the scanning periods t2 to t3 and t4 to t5 become longer, so that the EL display cells having high gray levels can emit light with high luminance. On the contrary, as the preliminary charging period c becomes longer, the number of occurrences of the crosstalk decreases, but the scan periods t2 to t3 and t4 to t5 become shorter, so that the high gradation electroluminescent display cells cannot emit light with high luminance.

SUMMARY OF THE INVENTION An object of the present invention is to provide a method and apparatus for driving an electroluminescent display panel which enables high gradation electroluminescent display cells to emit light with high luminance while reducing crosstalk through the data electrode line.

The method of the present invention for achieving the above object, for the electroluminescent display panel in which the data electrode lines and the scan electrode lines are formed to cross each other at a predetermined interval so that the electroluminescent display cells are formed in the intersection area, At the beginning of the horizontal driving period, data signals to be applied to each data electrode line are blocked, a first potential is applied to the scan electrode line to be scanned, and a second higher than the first potential to all other scan electrode lines. A method of driving an electroluminescent display panel in which a potential is applied and a preliminary charging step in which each data electrode line is electrically connected to each other by switching is performed. Here, the execution time of the preliminary charging step is changed for each data electrode line in inverse proportion to the magnitude of each data signal.

Accordingly, the execution time of the preliminary charging step is extended for the low gray electroluminescent display cells so that a relatively low current flows through the data electrode line, thereby reducing crosstalk through the data electrode line in the preliminary charging step. Can be. Further, since the execution time of the preliminary charging step is shortened for the high gray electroluminescent display cells, the scanning operation following the preliminary charging step becomes longer, so that the high gray electroluminescent display cells can emit light with high luminance. have.

An apparatus of the present invention for achieving the above object is a driving device of an electroluminescent display panel in which the data electrode lines and the scan electrode lines are formed to cross each other at a predetermined interval so that the electroluminescent display cells are formed in the crossing areas, And a data driver, a scan driver, charge switches, pulse generators, and a controller. The data driver is connected to signal-input terminals of the data electrode lines and processes and applies display data signals to the data electrode lines according to input switching control signals. The scan driver applies scan driving signals according to input switching control signals to the scan electrode lines. The charge switches are connected to the other ends of the data electrode lines, and electrically connect or disconnect the other ends of the data electrode lines to each other at the beginning of each horizontal driving period by input pulse signals. The pulse generators generate pulse signals for driving the charging switches according to input switching control signals so that the time that the other ends of the respective data electrode lines are connected to each other is inversely proportional to the magnitude of each data signal. Change per electrode line. The control unit inputs a display data signal and a switching control signal to the data driver, and inputs switching control signals to the scan driver and the pulse generators.

Hereinafter, preferred embodiments according to the present invention will be described in detail.

1 and 4, a method of driving the electroluminescent display panel 2 of FIG. 1 according to an embodiment of the present invention will be described in detail as follows. In FIG. 4, reference numerals S _3a to S _3e show signals applied to the respective data electrode lines 3a to 3e by way of example. Reference numeral S _Sn denotes a scan drive signal applied from the scan driver 6 to the nth scan electrode line 4a or 4b. Reference numeral S _{Sn + 1} denotes a scan drive signal applied from the scan driver 6 to the n + 1th scan electrode line 4b or 4c. Reference numerals S _25a to S _25e denote control signals that are equally applied to the respective charge switches 25a to 25e.

Each of the horizontal driving times a and b corresponds to the preliminary charging steps t1 to t3a, t1 to t3b and t1 to t3e and the scanning steps t3a to t3 and t3b to t3 for the respective data electrode lines 3a to 3e. , t3e to t3). Herein, the execution times t1 to t3a, t1 to t3b, and t1 to t3e of the preliminary charging step are changed for each data electrode line 3a to 3e in inverse proportion to the magnitudes of the data signals S _3a to S _3e . . The control process will be described in detail step by step as follows.

In the first times t1 to t3a of the nth horizontal driving time a, data signals applied to all the data electrode lines 3 are blocked. Further, by the operation of the scan switches 10a, ..., 10c, the ground potential as the first potential is applied to the nth scan electrode line to be scanned, and to all other scan electrode lines other than the nth scan electrode line. A second potential higher than the first potential is applied. In addition, all the data electrode lines 3 are electrically connected to each other by turning on all of the charging switches 25. Accordingly, the parasitic capacitors of the electroluminescent cells 1 of the n−1 th scan electrode line that were emitted at the scan time of the previous horizontal driving time are discharged, thereby causing the parasitic capacitors of all other electroluminescent cells 1 to be discharged. Are charged, the potential of all data electrode lines rises uniformly.

Next, at the end time t3a of the first time t1 to t3a of the nth horizontal driving time a, the first charge switch 25a is turned off (trn off) and at the same time, the current magnitude I A display data signal of ₄ is applied to the first data electrode line 3a.

Next, at the end time t3b of the second time t1 to t3b of the nth horizontal driving time a, the second charge switch 25b is turned off and the display of the current magnitude I ₂ is performed. The data signal is applied to the second data electrode line 3b.

At the end time t3e of the third time t1 to t3e of the nth horizontal driving time a, the mth charge switch 25b is turned off and the display data signal of the current magnitude I ₂ m is applied to the data electrode line 3e.

The above steps apply equally to the remaining data electrode lines 3c, ..., 3d.

As above, data signals applied to all data electrode lines 3 are blocked at the first time t1 to t3e of the n + 1th horizontal driving time b. Further, by the operation of the scan switches 10a, ..., 10c, the ground potential as the first potential is applied to the n + 1 scan electrode line to be scanned, and all other scans other than the n + 1 scan electrode line are applied. A second potential higher than the first potential is applied to the electrode lines. In addition, all the data electrode lines 3 are electrically connected to each other by turning on all of the charging switches 25. Accordingly, the parasitics of the electroluminescent cells 1 of the nth scan electrode line that were emitted at the scan times t3a to t3, t3b to t3, and t3e to t3 of the previous nth horizontal driving time a. As the capacitors are discharged, the parasitic capacitors of all other electroluminescent cells 1 are charged, so that the potentials of all the data electrode lines rise uniformly.

Next, at the end time t3e of the first time t3 to t3e of the n + 1th horizontal driving time b, the mth charge switch 25e is turned off (trn off) and the current A display data signal of size I ₃ is applied to the m th data electrode line 3e.

Next, at the end time t3b of the second times t3 to t3b of the n + 1th horizontal driving time b, the second charge switch 25b is turned off and the current magnitude I ₁ The display data signal is applied to the second data electrode line 3b.

At the end time t3a of the third time t3 to t3a of the n + 1th horizontal driving time b, the first charge switch 25a is turned off and the display of the current magnitude 0 (zero) is performed. The data signal is applied to the first data electrode line 3a.

The above steps apply equally to the remaining data electrode lines 3c, ..., 3d.

According to the driving method of the present invention as described above, the preliminary charging time (t1 ~ t3a, t1 ~ t3b, t1 ~ t3e) is inversely proportional to the magnitude of each data signal (S _3a to S _3e ) of each data electrode line (3a) To 3e). Accordingly, the preliminary charging time is increased for the low gray electroluminescent display cells so that a relatively low current flows through the data electrode lines 3a to 3e, so that crosstalk through the data electrode line in the preliminary charging step is reduced. Can be. In addition, since the preliminary charging time is shortened for the high gray electroluminescent display cells, and the scanning time following the preliminary charging time becomes longer, the high gray electroluminescent display cells can emit light with high luminance.

5 shows an internal configuration of the data driver 5 of the driving device of the electroluminescent display panel according to the present invention. 4 and 5, the data driver 5 includes an interface 30, a latch 31, a digital-to-analog converter 32, a driver circuit 33, and an output unit 34. .

The interface 30 interfaces the display data signals from the control unit 21 to the latch 31 and interfaces the timing control signals from the control unit 21 to the latch 31 and the digital-analog converter 32. ) And the drive circuit 33. The display data signal from the interface 30 is temporarily stored in the latch 31 and then input to the digital-to-analog converter 32. The digital-analog converter 32 operating in accordance with the timing control signals from the interface 30 converts the display data signal from the latch 31 into an analog signal and inputs it to the driving circuit 33.

The driving circuit 33 operating according to the timing control signals from the interface 30 drives the current sources 8 according to the display data signal from the digital-analog converter 32 to display the display data signal by the current. Generate. The output unit 34 outputs the display data signal from the driving circuit 33 to the data electrode lines 3. Here, as described above, the application time of the display data signal at each horizontal driving time (a, b) by the timing control signals from the control unit 21 is the magnitude of each data signal (S _3a to S _3e ) Each data electrode line 3a to 3e changes in proportion to.

6 shows the internal configuration of the charge switches 25 and the pulse generating circuit 26 of the driving device of the electroluminescent display panel according to the present invention. FIG. 7 shows the pulse generation circuit 26 of FIG. 6 in detail. 6 and 7, the charge switches 25 are connected to the other ends of the data electrode lines 3 opposite to the signal-input ends of the data electrode lines 3 so that each of the horizontal driving cycles is input by the input pulse signals. Initially, the other ends of the data electrode lines are electrically connected to or separated from each other. The pulse generators 26a to 26e which are connected to each of the charging switches 25 25a to 25e and constitute the pulse generating circuit 26 are connected to switching control signals input from the control unit (see 21 in FIG. 1). By generating pulse signals for driving the charge switches 25a to 25e accordingly, each data electrode line is inversely proportional to the magnitude of each data signal when the time at which the other ends of the respective data electrode lines 3a to 3e are connected to each other. (3a to 3e) to change. The related operation is as described above with reference to FIG. 4.

Referring to FIG. 8, the preliminary charging algorithm of the control unit (see 21 of FIG. 1) of the driving device of the electroluminescent display panel according to the present invention will be described as follows.

When the horizontal synchronization signal is input (step S1), the data signal of each data electrode line (3a to 3e in FIG. 1) input from the internal memory of the control unit (see 21 in FIG. 1) to the data driver (5 in FIG. 5). Is read (step S2). Next, a preliminary charging time inversely proportional to the magnitude of each data signal is set for each data electrode line (step S3). Next, the operation of the data driver (5 in FIG. 5) and the pulse generation circuit (26 in FIG. 6) is controlled in accordance with the set preliminary charging time (steps S4 and S5). The related operation is as described above with reference to FIG. 4. The steps S1 to S5 are repeatedly performed at each horizontal driving time (step S6).

As described above, according to the method and apparatus for driving an electroluminescent display panel according to the present invention, the execution time of the preliminary charging step is extended for the low gradation electroluminescent display cells, so that a relatively low current is transmitted through the data electrode line. As a result, crosstalk through the data electrode lines in the preliminary charging step can be reduced. In addition, since the execution time of the preliminary charging step is shortened for the high gray electroluminescent display cells, the scanning operation subsequent to the preliminary charging step becomes long, so that the high gray electroluminescent display cells can emit light with high luminance.

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 (5)

For an electroluminescent display panel in which data electrode lines and scan electrode lines are formed to cross each other at predetermined intervals so that electroluminescent display cells are formed in the crossing areas, at the beginning of each horizontal driving period, each data electrode Data signals to be applied to the line are cut off, a first potential is applied to the scan electrode line to be scanned, a second potential higher than the first potential is applied to all other scan electrode lines, and each data electrode line is switched In the driving method of the electroluminescent display panel performing a pre-charge step electrically connected to each other by, And an execution time of the preliminary charging step is changed inversely with each data electrode line in inverse proportion to the magnitude of each data signal. The method of claim 1, And when the preliminary charging step is completed, a scanning step is performed on the scan electrode line to be scanned until the end of each horizontal driving cycle. The method of claim 2, wherein the injection step, Each data electrode line is electrically isolated from each other by switching; The first potential of the scan electrode line to be scanned is sustained and the second potential of all other scan electrode lines is sustained; And Wherein each data signal is applied to each data electrode line such that selected electroluminescent display cells of the scan electrode line to be scanned emit light. The method of claim 1, wherein in the preliminary charging step, And the data electrode lines are commonly connected together with a cathode of a zener diode, and wherein the first potential is applied to an anode of the zener diode. A driving device of an electroluminescent display panel in which data electrode lines and scan electrode lines are formed to cross each other at predetermined intervals so that electroluminescent display cells are formed in the crossing areas. A data driver connected to signal-input terminals of the data electrode lines and processing and applying display data signals to the data electrode lines according to input switching control signals; A scan driver for applying scan driving signals according to input switching control signals to the scan electrode lines; Charge switches connected to the other ends of the data electrode lines to electrically connect or disconnect the other ends of the data electrode lines from each other at the beginning of each horizontal driving period by input pulse signals; Generate pulse signals for driving the charging switches according to input switching control signals, such that the time for which the other ends of the respective data electrode lines are connected to each other varies inversely with the magnitude of each data signal. Pulse generators; And And a control unit configured to input a display data signal and a switching control signal to the data driver and to input switching control signals to the scan driver and the pulse generators.

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