KR20040089246A - Method and apparatus of driving electro-luminescence display panel by selective scan - Google Patents

Abstract

PURPOSE: A method and an apparatus for driving an electro-luminescence display panel by using a selective scan are provided to drive the scan electrode lines selectively set at the selected display mode and drive the all data electrode lines by a unit frame. CONSTITUTION: A method for driving an electro-luminescence display panel by using a selective scan includes the steps of: an entire driving step of driving all scan electrode lines and all data electrode lines by a unit frame when the first display mode is set by the user; and a selective driving step of selectively driving the selectively set scan electrode lines and all data electrode lines by a unit frame when the second display mode is set by the user.

Description

Method and apparatus for driving electroluminescent display panel by selective scanning {Method and apparatus of driving electro-luminescence display panel by selective scan}

The present invention relates to a method and an 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 elements are formed in the crossing regions. The present invention relates to a method and an apparatus for driving an electroluminescent display panel.

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 elements 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 generates data current signals from the current sources 8 in accordance with the display data signals from the controller 21 to generate the data electrode lines. (3) is driven.

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, FR denotes a unit frame, V _SYNC denotes a vertical synchronization signal, and S _Sn denotes a scan driving signal applied from the scan driver 6 to the nth scan electrode line.

The unit frame FR is set to the time from the falling time point T0 of the vertical synchronization signal V _SYNC to the next falling time point T _n . At the first time T0 to T1 from the falling time point T0 of the vertical synchronization signal V _SYNC to the first time point T1, the signal S _S1 applied to the first scan electrode line 4a is The first scan electrode line 4a is scanned by having the ground voltage V _G , and data current signals are applied to all the data electrode lines 3. Accordingly, the electroluminescent elements 1 of the first scan electrode line 4a emit light with grayscales corresponding to the data current signals. The above operation is performed on the second scan electrode line 4b at the second time T1 to T2, is performed on the third scan electrode line at the third time T2 to T3, and at the nth time. The nth scan electrode line 4c is performed.

1 to 3B, the internal operation of the scan driver 6 of FIG. 1 for realizing the driving method of FIG. 2 will be described as follows. In FIGS. 3A and 3B, reference numeral S _TP denotes a signal input from the controller 21 to the data input terminal D of the first D-type flip-flop, and S _PC denotes all D signals from the controller 21. A preliminary discharge signal is applied to the clock terminals CLK of the type flip-flops, S _S1 is a signal applied to the first scan electrode line 4a, and S _S2 is applied to the second scan electrode line 4b. A signal, and S _Sn , respectively, indicate a signal applied to the nth scan electrode line 4c.

At a time before and after the first horizontal synchronization time point T0, a voltage of a logic "High" state is applied to the data terminal D of the first D-type flip-flop, and the first horizontal synchronization time point is applied. At (T0), a pulse of the preliminary discharge signal S _PC is applied. Accordingly, only the signal S _S1 applied to the first scan electrode line 4a at the first horizontal driving time H1 is in a low logic state (Logic “Low” state) and the remaining scan electrode lines 4b and 4c. The signals applied to) become high logic states.

In the preliminary charging steps T0 ˜ T0 ′ of the first horizontal driving time H1, data signals applied to all data electrode lines 3 are blocked. In addition, all data electrode lines 3 are connected to the charge voltage determiner 22 by the operation of the charge switches 25. Accordingly, the parasitic capacitors of the electroluminescent elements 1 of the n−1 th scan electrode line, which have been emitted at the scan time of the previous horizontal driving time, are discharged, thereby being set by the charging voltage determiner 22. The potential of all data electrode lines becomes uniform as the potential.

In the scanning steps T0 'to T1 of the first horizontal driving time H1, all data electrode lines 3 are electrically separated from each other by the operation of the charge switches 25, and the data current signals are separated from each other. Applied to the lines 3, the electroluminescent elements of the first scan electrode line emit light as a gray level in accordance with the data current signals. Here, since the potentials of all the data electrode lines 3 are higher than the ground potentials due to the preliminary charging steps T0 ˜ T0 ′, voltage may be applied to the selected electroluminescent elements more quickly, thereby increasing luminance.

The same operation principle applies to the remaining horizontal driving times H2 to H _n .

According to the conventional method and apparatus for driving an electroluminescent display panel as described above, all the scan electrode lines 4 are driven per unit frame FR. Accordingly, since all display areas of the electroluminescent display panel 2 are driven, the user cannot see only a part of the display area by his selection at higher luminance.

It is an object of the present invention to provide a method and apparatus for driving an electroluminescent display panel which allows a user to see only a portion of the display area of his choice at higher luminance.

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.

3A is a circuit diagram illustrating an internal configuration of the scan driver of FIG. 1 for realizing the driving method of FIG. 2.

FIG. 3B is a voltage waveform diagram illustrating the signals of FIG. 3A.

4 is a timing diagram illustrating a method of selectively driving the electroluminescent display panel of FIG. 1 in accordance with an embodiment of the present invention.

FIG. 5 is a flowchart illustrating an operation algorithm of the controller of FIG. 1 for performing the selective driving method of FIG. 4.

6A is a circuit diagram illustrating an internal configuration of the scan driver of FIG. 1 performing the selective driving method of FIG. 4.

6B is a voltage waveform diagram illustrating the signals of FIG. 6A.

FIG. 7 is a circuit diagram illustrating an internal configuration of the data driver of FIG. 1 controlled by the operation algorithm of FIG. 5.

<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.

The method of the present invention for achieving the above object is a driving method 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 electroluminescent elements are formed in the crossing regions. A driving step and a selective driving step. In the all driving step, when the first display mode is set by the user, all the scan electrode lines and all the data electrode lines are driven every unit frame. In the selective driving step, when the second display mode is set by the user, the selectively set scan electrode lines and all data electrode lines are driven per unit frame.

An apparatus of the present invention for achieving the above object is a drive 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 electroluminescent elements are formed in the crossing areas. And a driver, a scan driver, 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 control unit inputs a display data signal and a switching control signal to the data driver and a switching control signal to the scan driver, so that when the first display mode is set by the user, all the scan electrode lines and all the data electrode lines When the second display mode is set by the user, the scan electrode lines and all the data electrode lines, which are selectively set, are driven per unit frame.

According to the method and apparatus for driving the electroluminescent display panel of the present invention, scan electrode lines and all data electrode lines selectively set in the second display mode are driven every unit frame. Accordingly, the user can see only a part of the display area by his selection at higher luminance.

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

The driving method of the electroluminescent display panel (2 of FIG. 1) according to the present invention includes a whole driving step and a selective driving step. In the all driving step, when the all display mode as the first display mode is set by the user, all the scan electrode lines (4 in Fig. 1) and all the data electrode lines (3 in Fig. 1) are driven per unit frame ( 2 and its description). In the selective driving step, when the selective display mode as the second display mode is set by the user, the selectively set scan electrode lines and all the data electrode lines (3 in FIG. 1) are driven per unit frame.

1 and 4, a method of selectively driving the electroluminescent display panel 2 in the selective display mode according to an embodiment of the present invention will be described. In FIG. 4, FR denotes a unit frame, V _SYNC denotes a vertical synchronization signal, S _S1 denotes a scan driving signal applied from the scan driver 6 to the first scan electrode line 4a, and S _Si denotes a scan driver ( 6 is a scan drive signal applied to the i th scan electrode line, S _{S (i + 1)} is a scan drive signal applied from the scan driver 6 to the (i + 1) th scan electrode line, and S _Sj is The scan driving signal applied from the scan driver 6 to the j th scan electrode line, and the S _{S (j + 1)} represents the scan driving signal applied from the scan driver 6 to the jth (j + 1) scan electrode line. S _Sn indicates a scan drive signal applied from the scan driver 6 to the nth scan electrode line 4c, respectively.

The unit frame FR is set to the time from the falling time point T0 of the vertical synchronization signal V _SYNC to the next falling time point T _n .

The first to (i-1) th scan electrode lines are not scan electrode lines of a region selected by the user in the second display mode. Accordingly, the scan pulse of the ground voltage V _G is not generated in the first through (i-1) scan electrode lines, and the bias voltage V _CC is continuously applied to each unit frame FR.

Similarly, the j + 1 to n-th scan electrode lines are not scan electrode lines of a region selected by the user in the second display mode. Accordingly, the scan pulse of the ground voltage V _G is not generated in the j + 1 to n-th scan electrode lines, and the bias voltage V _CC is continuously applied to each unit frame FR.

The i th to j th scan electrode lines are scan electrode lines of a region selected by a user in the selection display mode. Accordingly, scan pulses of the ground voltage V _G are repeatedly generated in the i th through j th scan electrode lines in the unit frame FR.

At the first time T0 to T1 from the falling time point T0 of the vertical synchronization signal V _SYNC to the first time point T1, the signal S _Si applied to the i th scan electrode line is the ground voltage (T). V _g ) scans the i-th scan electrode line, and applies data current signals to all the data electrode lines 3. Accordingly, the electroluminescent elements 1 of the i th scan electrode line emit light with grayscales according to the data current signals. The above operation is performed on the (i + 1) th scan electrode line at the second time T1 to T2, and is performed on the (i + 2) th scan electrode line at the third time T2 to T3. , _{(J-i + 1)} is performed on the j th scan electrode line at the times T _(j- i) to T _{(j-i + 1)} .

The sequential scanning operation for the i th to j th scan electrode lines that are the scan electrode lines of the selected region is repeated in the unit frame FR. Accordingly, the user may view only a part of the display area brighter according to his / her choice. For example, when a QVGA mode electroluminescent display panel with 320 data electrode lines 3 and 240 scan electrode lines 4 is used, and the luminance of the electroluminescent element is 12,000 cd / m ² , the selection The luminance of the unit scan electrode line in the region is 50 cd / m ² (12,000 / 240 cd / m ² ) according to the prior art. On the other hand, in the selective display mode according to the present invention, when there are 32 scan electrode lines in the selection area, the luminance of the unit scan electrode line in the selection area is 375 cd / m ² (12,000 / 32 cd / m ² ), It is 7.5 times higher than that.

1 and 5, an operation algorithm of the controller 21 of FIG. 1 for performing the selective driving method of FIG. 4 will be described.

First, it is checked whether the selective display mode is set by the user (step S1).

If the selective display mode is not set by the user and the entire display mode is set, all the scan electrode lines 4 and all the data electrode lines 3 are driven (step S21). This step S21 is repeated until an external end signal is input (step S22).

If the selective display mode has been set by the user, the selective display region is read accordingly (step S31). Next, the scan electrode lines to be driven in accordance with the read selected display area are set (step S32). Next, the set scan electrode lines and all data electrode lines 3 are driven (step S33). This step S33 is repeatedly performed until an external end signal is input (step S34).

The configuration and operation of the scan driver 6 of FIG. 1 for performing the selective driving method of FIG. 4 will be described with reference to FIGS. 1, 6A, and 6B. In FIGS. 6A and 6B, reference numeral S _TP denotes a signal input from the controller 21 to the data input terminal D of the first D-type flip-flop, and S _PC denotes all D signals from the controller 21. A preliminary discharge signal is applied to the clock terminals CLK of the type flip-flops, S _S1 is a signal applied to the first scan electrode line 4a, and S _S2 is applied to the second scan electrode line 4b. And S _S8 indicate a signal applied to the eighth scan electrode line, respectively.

The scan driver 6 of FIG. 1, which performs the selective driving method of FIG. 4, includes a first scan pulse generator of D-type flip-flops and a second scan pulse generator of OR gates.

In the first scan pulse generator, the D-type flip-flops corresponding to each of the scan electrode lines 4 are connected in series. These D flip-flops sequentially generate a first scan pulse.

The second scan pulse generator includes OR gates corresponding to each of the D flip-flops of the D flip-flop array. The output signals Q21 to Q28 of each of the D-type flip-flops are input to the first input terminal of each of the OR gates. In addition, the line selection signal HI or LO from the controller 21 is input to the second input terminal of each of the OR gates. An output terminal of each of the OR gates is connected to each of the scan electrode lines 4. Each of the OR gates applies a second scan pulse to each of the scan electrode lines 4 according to the line select signal HI or LO.

In the initial driving time INI, at a time before and after the first horizontal synchronization time point T _PO , a high logic state (Logic “High” state) is applied to the data terminal D of the first D-type flip-flop. The voltage is applied, and the pulse of the preliminary discharge signal S _PC is applied to the clock terminals CLK of all the D-type flip-flops at the first horizontal synchronization time point T _PO . Accordingly, in the first horizontal driving time T _PO ˜T _P1 included in the initial driving time INI, only the output signal Q21 of the first D-type flip-flop has a low logic state “Low” state. And the output signals Q22 to Q28 of the remaining D-type flip-flops are in a high logic state. However, since the high logic signal HI is applied to the data input terminal of the first OR gate, it is applied to the output signal S _S1 of the first OR gate, that is, the first scan electrode line 4a. The signal S _S1 to be maintained maintains a high logic state.

The pulse of the preliminary discharge signal S _PC is applied to the clock terminals CLK of all the D-type flip-flops at the second horizontal synchronization time point T _P1 of the initial driving time INI. Accordingly, only the output signal Q22 of the second D-type flip-flop becomes the low logic state at the second horizontal driving time T _P1 to T0 included in the initial driving time INI and the remaining D-type flip-flops The output signals Q21, Q23 through Q28 are in a high logic state. However, since the high logic signal HI is applied to the data input terminal of the second OR gate, it is applied to the output signal S _S2 of the second OR gate, that is, the second scan electrode line 4b. The signal S _S2 to be maintained maintains a high logic state.

The pulse of the preliminary discharge signal S _PC is applied to the clock terminals CLK of all the D-type flip-flops at the first horizontal synchronization time point T0 of the first frame FR1. Accordingly, only the output signal Q23 of the third D-type flip-flop is in a low logic state at the first horizontal driving time H1 of the first frame FR1, and the output signals Q21 of the remaining D-type flip-flops are low. , Q22 and Q24 to Q28) become a high logic state. In addition, since the low logic signal HI is applied to the data input terminal of the third OR gate, the output signal S _S3 of the third OR gate, that is, the third scan electrode line included in the selected region. The signal S _S3 applied to maintains a low logic state.

Accordingly, in the preliminary charging steps T0 ˜ T0 ′ of the first horizontal driving time H1, data signals applied to all data electrode lines 3 are blocked. In addition, all data electrode lines 3 are connected to the charge voltage determiner 22 by the operation of the charge switches 25. Accordingly, the parasitic capacitors of the electroluminescent elements 1 of the n−1 th scan electrode line, which have been emitted at the scan time of the previous horizontal driving time, are discharged, thereby being set by the charging voltage determiner 22. The potential of all data electrode lines becomes uniform as the potential.

In the scanning steps T0 'to T1 of the first horizontal driving time H1, all data electrode lines 3 are electrically separated from each other by the operation of the charge switches 25, and the data current signals are separated from each other. Applied to the lines 3, the electroluminescent elements of the first scan electrode line emit light as a gray level in accordance with the data current signals. Here, since the potentials of all the data electrode lines 3 are higher than the ground potentials due to the preliminary charging steps T0 ˜ T0 ′, voltage may be applied to the selected electroluminescent elements more quickly, thereby increasing luminance.

The above operation is sequentially performed on the fourth and fifth scan electrode lines of the selected region at the remaining two horizontal driving times H2 and H3. On the other hand, when the unit horizontal driving time elapses three times, for example, at the second horizontal synchronization time point T1 and the second 'horizontal synchronization time point T1', the data terminal D of the first D-type flip-flop is applied. A high logic state voltage is applied. Accordingly, the operations in the first to third horizontal driving times H1 to H3 are continuously repeated.

FIG. 7 illustrates an internal configuration of the data driver of FIG. 1 controlled by the operation algorithm of FIG. 5. 1 and 7, the data driver 5 includes an interface 30, a latch 31, a digital-analog converter 32, a driver circuit 33, and an output unit 34.

The interface 30 interfaces the display data signal from the control unit 21 to the latch 31 and interfaces the timing control signal 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 signal from the interface 30 converts the display data signal from the latch 31 into an analog signal and inputs it to the drive circuit 33.

The drive circuit 33 operating according to the timing control signal from the interface 30 drives the current sources 8 in accordance with the display data signal from the digital-analog converter 32 to generate a display data signal by the current. Let's do it. The output unit 34 outputs the display data signal from the driving circuit 33 to the data electrode lines 3.

As described above, according to the method and apparatus for driving an electroluminescent display panel according to the present invention, the scan electrode lines and all data electrode lines selectively set in the selective display mode are driven per unit frame. Accordingly, the user can see only a part of the display area by his selection at higher 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 (4)

A method of driving 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 elements are formed in the crossing regions. A driving step of driving all scan electrode lines and all data electrode lines per unit frame when the first display mode is set by a user; And And driving the selectively set scan electrode lines and all data electrode lines per unit frame when the second display mode is set by the user. 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 elements 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; And The display data signal and the switching control signal are input to the data driver and the switching control signal is input to the scan driver. When the first display mode is set by the user, all scan electrode lines and all data electrode lines are driven every unit frame. And a control unit configured to drive selectively set scan electrode lines and all data electrode lines per unit frame when the second display mode is set by the user. The method of claim 2, wherein the scan drive unit, A first scan pulse generation unit in which flip-flops corresponding to each of the scan electrode lines are connected in series so that the flip-flops sequentially generate a first scan pulse; OR gates corresponding to each of the flip-flops of the flip-flop array are provided, an output signal of each of the flip-flops is input to a first input terminal of each of the OR gates, A line select signal from the controller is input to a second input terminal of each of the OR gates, and an output terminal of each of the OR gates is connected to each of the scan electrode lines, thereby providing the OR. OR) A driving device of an electroluminescent display panel, wherein each of the gates includes a second scan pulse generator for applying a second scan pulse to each of the scan electrode lines according to the line selection signal. The method of claim 2, An electroluminescent display further connected to the other ends of the data electrode lines, the charge switches electrically connecting or disconnecting the other ends of the data electrode lines from each other at the beginning of each horizontal driving period according to a switching control signal from the controller The drive unit of the panel.