DE102006014873B4 - Driving method for an electroluminescent display device - Google Patents

Abstract

A method of driving an electroluminescent display device (400) comprising: an electroluminescent display panel (410) having red, green and blue subpixels (416) in areas selected by a plurality of data lines (DL1-DLk) and a plurality of scan lines (Scan n_1, scan n_2), an integrated scan driver circuit (440, 440 ') for driving the scan lines (scan n_1, scan n_2) and an integrated data driver circuit (430) for driving the data lines (DL1-DLk) and a multiplexer unit (450) for selectively connecting output channels (OC1-OCj) of the integrated data driver circuit (430) to one of at least two of the data lines, the method comprising the steps of:
- supplying selection signals of two multiplexed clock signals (MUX CLK1, MUX CLK2) to the multiplexer unit (450);
- applying a first selection signal of the multiplexed clock signals (MUX CLK1, MUX CLK2) to connect output channels (OC1-OCj) of the integrated data driver circuit (430) to subpixels (416) connected to odd scan lines; and
- applying a second selection signal of the multiplexed clock signals (MUX CLK1, MUX CLK2) to connect output channels (OC1-OCj) of the integrated data driver circuit (430) to subpixels (416) connected to straight scan lines,
wherein each of the subpixels comprises an EL cell connected between a voltage source (Vdd) and a ground terminal (GND),
wherein the first selection signal is turned on and off every 1/6 of a horizontal period, the second selection signal being switched to a state opposite to the first selection signal,
wherein the red (R), green (G) and blue (B) subpixels (416) are arranged along the same data line,
wherein the scan driver circuit (440, 440 ') includes a first scan integrated driver circuit (440) for driving a first set of scan lines (Scan1_1 to Scan n_1) and a second scan integrated drive circuit (440') for driving from a second set of scan lines (Scan1_2 to Scan n_2),
wherein scan pulses maintaining their on-state during one-sixth of the horizontal period are applied sequentially to the scan lines (scan n_1, scan n_2),
wherein a pair of scan lines (Scan1_1, Scan1_2) of the first and second integrated scan driver circuits (440, 440 ') are disposed adjacent to each other and the pair of scan lines (Scan1_1, Scan1_2) of the first and second integrated scan lines Driver circuit (440, 440 ') is alternately connected to the sub-pixels in the row direction, and
wherein all sub-pixels in each row correspond to only one color of red, green or blue, so that the pair of scan lines (Scan1_1, Scan1_2) applies scan signals only to sub-pixels having the one color in the row.

Description

BACKGROUND OF THE INVENTION

Field of the invention

The present invention relates to a display device and driving method for the same, and more particularly to an electroluminescent display device and a driving method for the same.

Description of the Prior Art

Cathode ray tubes (CRTs) are heavy and bulky as display devices. To overcome these disadvantages of CRTs, flat display devices have been developed. Examples of flat display devices include a liquid crystal display device (LCD), a field emission display device (FED), a plasma display device (PDP), and an electroluminescent display device (EL). The EL display device is a self-luminous display device in which light is emitted from a fluorescent material in which recombination of electrons and holes occurs. The EL display devices may be divided into inorganic and organic EL display devices depending on the fluorescent materials and structures used. Unlike LCDs, the organic EL display device does not require a separate light source. Thus, the organic EL display device (hereinafter referred to as OLED) has a fast response time as compared with CRTs.

1 shows a sectional view of an EL cell in a conventional organic electroluminescent display panel. In particular shows 1 a sectional view of an organic EL structure for explaining the light-emitting structure of the OLED device. According to 1 For example, the OLED device comprises an electron injection layer 4 , an electron transport layer 6 , an organic emission layer 8th a hole transport layer 10 and a hole injection layer 12 stacked successively between a cathode 2 and an anode 14 are arranged. If between a transparent electrode, for example. The anode 14 and a metal layer, such as the cathode 2 When a predetermined voltage is applied, electrons move from the cathode 2 through the electron injection layer 4 and the electron transport layer 6 in the direction of the emission layer 8th , Likewise, holes move from the anode 14 through the hole injection layer 12 and the hole transport layer 10 in the direction of the organic emission layer 8th , The electrons from the electron transport layer 6 and the holes from the hole transport layer 10 recombine in the organic emission layer 8th , which generates light. The light then goes out over the transparent electrode anode 14 the transparent electrode emitted.

2 Fig. 10 shows a circuit of a conventional organic EL display device. According to 2 For example, the conventional OLED device includes an organic EL display panel 16 , an integrated scan driver circuit (Scan D-IC) 18, an integrated data driver circuit (Data D-IC) 20, and a process controller 26 , The OLED panel 16 contains subpixels 22 that are formed in areas by a variety of scan lines SL1 to SLn and a variety of data lines DL1 to DLm are formed, which cross each other. The Scan D-IC 18 controls the scan lines SL1 to SLn on and the data D-IC 20 controls the data line DL1 to DLm at. In addition, the flow control controls 26 the timing of the control of the data D-IC 20 and the Scan D-IC 18 , Each of the subpixels 22 includes a voltage source VDD and a ground terminal GND, an OLED cell connected between the voltage source VDD and the ground terminal GND, and an OLED drive circuit 24 for driving the OLED cell in response to drive signals coming from the data line DL and the scan line SL be supplied. A pixel is made up of red (R), green (G) and blue (B) subpixels which are arranged horizontally adjacent to each other.

The OLED drive circuit 24 includes: a driving thin film transistor DT (hereinafter referred to as TFT) connected between the power source VDD and the OLED device is switched; a first switching TFT T1 that with the scan line SL and the data line DL is connected; a second switching TFT T2 that with the first switching TFT T1 and the driving TFT DT; a converter TFT MT between the voltage source VDD and a node of the first switching TFT T1 and the second switching TFT T2 is switched, wherein the converter TFT MT together with the driving TFT DT forming a current mirror circuit for converting a current into a voltage; and a storage capacitor Cst connected between the voltage source VDD and a node of the gates of the driving TFT DT and the converter TFT MT is switched. The driving TFT DT , the converter TFT MT, the first switching TFT T1 and the second switching TFT T2 are formed as P-channel metal oxide semiconductor field effect transistors (MOSFETs).

The driving TFT DT has a gate connected to the gate of the converter TFT MT connected, a source connected to the voltage source VDD and a drain, which is connected to the OLED device. The converter TFT MT has a source connected to the voltage source VDD and a drain connected to a drain of the first switching TFT T1 and with a source of the second switching TFT T2 connected is. The first switching TFT T1 has a source connected to the data line DL and a drain connected to a source of the second switching TFT T2 connected is. The second switching TFT T2 has a drain connected to the gates of the driving TFT DT and the converter TFT MT and connected to the storage capacitor CST.

The first and the second switching TFT T1 and T2 have gates connected to the scan line SL. The converter TFT MT and the driving TFT DT form a current mirror circuit, since they are designed to have the same electrical characteristics. When the converter TFT MT and the driving TFT DT are the same, the amount of current flowing through the converter TFT MT will be equal to the amount of current flowing through the driving TFT DT.

The flow control 26 generates a data control signal for controlling the data D-ICs by means of synchronization signals supplied from an external system, for example a graphics card 20 and a scan control signal for controlling the Scan D-IC 18 , The process control continues 26 the data IC 20 Video data supplied from an external system. The Scan D-IC 18 generated as a function of the flow control 26 supplied scan control signal scan signals.

3 shows a waveform of scan signals that the scan lines in 2 be supplied. As in 3 shown, the scan signals are sent to the scan lines SL1 to SLn created so that the scan lines SL1 to SLn be controlled sequentially. The data D-IC 20 supplies the data lines DL1 to DLm at each horizontal period 1H with data signals having a current level or a pulse width depending on the video data corresponding to that of the sequence controller 26 supplied data control signal. Here, the data D-IC 20 a number m of output channels 21 on, the 1: 1 with the data lines DL1 correspond to DLm.

The data D-IC 20 supplies each of the subpixels 22 with the data signal having a current level or pulse width proportional to input data. Each of the subpixels 22 emits light in proportion to one of the data line DL supplied amount of electricity. Since one pixel is formed of horizontally arranged red (R), green (G) and blue (B) subpixels, three data lines and one scan line are required to drive the conventional pixels.

In the conventional OLED device, the Scan D-IC 18 Outputs on, the 1 : 1 the scan lines SL1 to SLn in the row direction of the organic EL display panel 16 correspond and the data D-IC 20 has channels 21 on that the data lines DL1 to DLm of the organic EL display panel 16 in column direction 1 : 1 correspond. Because the output channels 21 of the data D-IC 20 1: 1 with the data lines DL1 until DLm match, are at data D-IC 20 as many output channels are required as data lines DL1 until DLm are present. Consequently, the conventional organic EL display device has the disadvantage that the price of the data D-IC 20 increases when the number of output channels 21 of the data D-IC 20 elevated. In addition, the number of output channels increases 21 as the size of the OLED panel increases.

US 2003/0174106 A1 describes a light-emitting display device in which sub-pixels of a pixel are arranged in the column direction.
JP 07 013511 A describes an electroluminescent display device in which a display panel is connected to two data drivers and two gate drivers arranged on opposite sides.

US 2004/0233184 A1 describes a display driver for a display device in which two gate drivers are arranged on opposite sides of the display surface and the data drivers are connected to the data lines via multiplexers.

US 2003/0231152 A1 describes a display device with OLEDs, in which two scan drivers are present and driving the OLED is driven current.

US 2004/0257322 A1 describes a display device with two gate drivers, each arranged on one and the opposite other side of the panel. Sub-pixels of a pixel are arranged in the row direction.

SUMMARY OF THE INVENTION

The present invention is directed to an electroluminescent display device and a driving method therefor, which substantially obviates one or more problems due to the limitations and disadvantages of the prior art.

The object of the present invention is to provide an EL display device and a driving method for the same, in which the number of output channels of an integrated data circuit can be minimized.

Another object of the present invention is to provide an EL display device and a driving method for the same, in which the integrated data circuit can be built into a panel.

Another object of the present invention is to provide an EL display device and a driving method for the same in which the manufacturing cost is reduced and to realize a compact panel.

Further advantages, objects and characteristics of the invention will be described below in the description and apparent to those skilled in the art upon examination of the following or may be learned by practice of the invention. The objects and other advantages of the invention may be realized and attained by the structure illustrated in the written description, the claims and the appended drawings.

The object is solved by the features of the claim.

In order to achieve the objects and advantages of the present invention, there is provided an electroluminescent display device including: an electroluminescent display panel having red, green and blue sub-pixels in areas formed by a plurality of data lines and a plurality of scan lines; an integrated scan driver circuit for driving the scan lines; and an integrated data driver circuit for driving the data lines, the integrated data driver circuit having no more output channels than half of the plurality of data lines.

According to another embodiment, an electroluminescent display device includes: an electroluminescent display panel having red, green and blue sub-pixels in areas formed by a plurality of column-direction data lines and a plurality of line-scan lines; a first integrated scan driver circuit on one side of the electroluminescent display panel and a second integrated scan driver circuit on an opposite side of the electroluminescent display panel, the first set of scan lines and the second set of scan lines alternately are connected to the subpixels in the row direction via the electroluminescent panel.

In another aspect, an electroluminescent display device includes: an electroluminescent display panel having red, green and blue sub-pixels in areas formed by a plurality of data lines and a plurality of scan lines; an integrated scan driver circuit for driving the scan lines; and an integrated data driver circuit for driving the data lines; and a multiplexer unit for selectively connecting output channels of the integrated data driver circuit to one of at least two of the data lines, wherein the red, green and blue subpixels are arranged in the same direction as the plurality of data lines and form a unit pixel.

Another aspect relates to a method of driving an electroluminescent display device having an electroluminescent display panel with red, green and blue sub-pixels in areas formed by a plurality of data lines and a plurality of scan lines, a scan driver integrated circuit for driving the scan lines and an integrated data driver circuit for driving the data lines and a multiplexer unit for selectively connecting the output channels of the integrated data driver circuit to one of at least two of the data lines, the method comprising: supplying selection signals from at least two multiplexed-to-multiplexer signals; Applying a first selection signal of the multiplexed clock signals to connect output channels of the integrated data driver circuit to subpixels connected to odd scan lines; and applying a second selection signal of the multiplexed clock signals to connect output channels of the integrated data driver circuit to subpixels connected to even scan lines.

The foregoing general description and the following detailed description of the present invention should be taken as exemplary and explanatory description. Further, the description will serve to further explain the claimed invention.

list of figures

• 1 eine Schnittdarstellung einer EL-Zelle in einem herkömmlichen organischen Elektrolumineszenz-Anzeigepanel;
• 2 ein Schaltungsdiagramm einer herkömmlichen organischen EL-Anzeigevorrichtung;
• 3 einen Signalverlauf von Scan-Signalen, die an Scan-Leitungen von 2 angelegt werden;
• 4 eine EL-Anzeigevorrichtung gemäß einem Ausführungsbeispiel der vorliegenden Erfindung;
• 5 ein Schaltungsdiagramm einer EL-Anzeigevorrichtung gemäß 4;
• 6 zeigt Signale, die an die EL-Anzeigevorrichtung gemäß dem Ausführungsbeispiel der vorliegenden Erfindung angelegt werden, im Vergleich mit Signalen, die bei einer herkömmlichen EL-Anzeigevorrichtung erzeugt werden;
• 7 zeigt Datenströme, die an die EL-Anzeigevorrichtung gemäß dem Ausführungsbeispiel der vorliegenden Erfindung angelegt werden.

The accompanying drawings, which are given a further understanding of the invention, form a part of this application and illustrate embodiments of the invention. Together with the description, they serve to explain the principles of the invention. In the drawings shows:

• 1 a sectional view of an EL cell in a conventional organic electroluminescent display panel;
• 2 a circuit diagram of a conventional organic EL display device;
• 3 a waveform of scan signals sent to scan lines of 2 be created;
• 4 an EL display device according to an embodiment of the present invention;
• 5 a circuit diagram of an EL display device according to 4 ;
• 6 Fig. 12 shows signals applied to the EL display device according to the embodiment of the present invention as compared with signals generated in a conventional EL display device;
• 7 FIG. 15 shows data streams applied to the EL display device according to the embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Incidentally, whenever possible, the same reference numerals are used in the drawings to designate the same or similar parts.

4 shows an EL display device according to an embodiment of the present invention. Regarding 4 contains the EL display device 400 According to an embodiment of the present invention, an EL display panel 410 with a multitude of subpixels 416 which are formed in areas by scan lines SL1_1 to SLn_1 and SL1_2 to SLn_2 and data lines DL1 to DLk are formed, an integrated scan driver circuit (hereinafter referred to as Scan D-IC) 440 for driving the scan lines, an integrated data driver circuit (hereinafter referred to as data D-IC) 430 for driving the data lines, a multiplexer unit 450 for selectively connecting each of the output channels OC1 to OCj of the data D-IC 430 with a number i of data lines DL to DLk (where "i" is a positive integer greater than 2 is) and a flow control 460 for controlling the driving timing of the data D-IC 430 and the Scan D-IC 440 ,

As in 4 shown are the red (R), green (G) and blue (B) subpixels 416 arranged in the column direction, which is the same direction as that of the data lines DL and thus in the construction of a pixel 414 have a vertical strip shape. The vertical stripe-like pixel 414 is from R-. G and B sub-pixels are formed, which are arranged in the column direction, rather than in the row direction. As described above with respect to the conventional pixel, three data lines and one scan line are required to drive the conventional pixel. In contrast, one data line and three scan lines is required to make the vertical stripe-like pixel 414 in an embodiment of the present invention.

That is, in the prior art, the R, G, and B sub-pixels are arranged in a row direction, and thus three data lines extending from an upper portion of the panel are required. Further, a scan line extending from a side portion of the panel passes through and drives the conventional R, G, and B subpixels. In the case of the vertical stripe-like pixel 414 For example, since the R, G and B subpixels are arranged in the column direction, three scan lines extending from the side portion of the panel and a data line extending from the top of the panel and the column direction R are required , G and B subpixels and drives the R, G and B subpixels.

The EL display device 410 with vertical stripe-like pixels 414 can the number of output channels OC1 to OCj of the data D-IC 430 around 1 / 3 reduce compared to the state of the art. A number of i multiplexed clock signals MUX CLK become the multiplexer unit 450 fed so that each of the output channels OC1 to OCj of the data D-IC 430 selectively with a number i of data lines DL1 to DLk (where i is a positive integer> 1). Thus, the for driving the Datenleitugen DL required number of output channels OC1 to OCj of the data D-IC 430 around 1 / i be reduced. In the embodiment according to 4 become two multiplexes MUX CLK wherein one of at least two data lines is selectively connected to each of the output channels of the data D-IC 430 connected is. However, this embodiment of the present invention is not limited to such a configuration. Each of the output channels OC1 to OCj of the data D-IC 430 can be multiplexed with three or more data lines, which are used to drive the data lines DL required number of output channels OC1 to OCj of the data D-IC 430 is reduced. Consequently, an EL display device of the present invention allows the output channels OC1 to OCj of the data D-IC 430 compared to a conventional data D-IC order 1 / 3i to reduce.

With renewed reference to 4 is a pair of Scan D-ICs, assuming that two multiplexed clock signals are used 440 and 440 ' on the right and left side of the EL display panel 410 present, that is, a first scan D-IC 440 and a second D-IC 440 ' , That differs from the first scan D-IC 440 extending scan lines SL1_1 to SLn_1 and that differs from the second scan D-IC 440 ' extending scan lines SL1_2 to SLn_2 are in an alternating manner with the subpixels 416 in the row direction via the EL display panel 410 connected. This means. one of the pairs of scan lines SL1_1 to SLn_1 that from the first scan D-IC 440 be controlled and SL1_2 to SLn_2 that by second scan D-IC 440 is controlled with the subpixel 416 connected to the vertical strip-like pixel 414 forms. For example, the scan lines SL1_1 to SLn_1 that from the first scan D-IC 440 are connected to the odd subpixels and the scan lines SL1_2 to SLn_2 that from the second scan D-IC 440 ' are connected to the even subpixels.

In the EL display device according to 4 can the multiplexer 450 with the two multiplexed files MUX CLK together with the vertical stripe-like pixel structure 414 the number of output channels OC1 to OCj of the data D-IC 430 which is used to control the data lines DL are required to 1 / 6 to reduce. Specifically, the total reduction is 1 / 2 * 1/3, for a total of 1 / 6 results since the multiplexer 450 with the two multiplexed files MUX CLK the number of output channels OC1 to OCj of the data D-IC 430 around 1 / 2 reduced and the vertical stripe-like pixel 414 the number of output channels OC1 to OCj of the data D-IC 430 around 1 / 3 reduced. Thus, a D-IC can be used, compared to the prior art only 1 / 6 having the output channels, whereby the manufacturing costs are reduced and a compact panel is realized.

5 shows a detailed circuit diagram of an EL display device according to 4 , With reference to the 4 and 5 can in the EL display device 400 according to an embodiment of the present invention, the number of outputs OC1 to OCj of the data D-IC 430 by using the vertical stripe-like pixel structure, wherein the number of output channels of the data D-IC is l / i by using the multiplexer unit 450 and a number i of multiple-bit clock signals MUX CLK is reduced, so the ratio of output channels OCl to OCj to data lines DL l / i, whereby the manufacturing cost is reduced and a compact EL display panel is realized. Here, the multiplexer unit connects 450 the output channels OC1 to OCj of the data D-IC 430 selectively with 1 / i the data lines DL1 to DLk (where i is a positive integer equal to or greater than 2). Thus, a data D-IC 430 in the embodiments of the present invention, no more output channels OC1 to OCj than half of the data lines DL on.

If the multiplexer unit 450 and the number i of the multiplexed clock signals are used, the scan lines must be increased by a number i, wherein the pulse width of the scan electrode signal to 1 / (3 * i) is narrower compared to the prior art. Even if the pulse width of the applied scan electrode signal to 1 / (3 * i) is narrower, this poses no problem in driving an EL display device. In the embodiments of Figs 4 and 5 Assume that two multiplexed clock signals are applied, two scan lines are arranged per subpixel line and the pulse width is around 1 / 6 narrower compared to the prior art.

In this embodiment, a 1_1 scan line Scan1_1 and a 1_2 scan line Scan1_2 split and connected to a first Subpixelleitung. A sum of pulse widths of the 1_1 scan signal Scan1_1 and the 1_2 scan signal Scan1_2 corresponds to 1 / 6 * pulse width of the first scan signal Scanl according to the prior art. On the right and left side of the EL display panel 410 are the first scan D-IC 440 and a second D-IC 440 ' arranged. The scan lines SLl_1 to SLn_1 that differ from the first D-IC scan 440 extend and the scan lines SL1_2 to SLn_2 that differ from the second scan D-IC 440 ' extend are in an alternating manner with the subpixels 416 in the row direction via the EL display panel 410 connected. That is, a pair of the electrode lines SL1_1 to SLn_1 that from the first scan D-IC 440 be controlled and the other of the pairs of electrode lines SLl_2 to SLn_2 that from the second scan D-IC 440 are alternating with the subpixels 416 each connected to the vertical strip-like pixels 414 form. For example, the scan lines SL1_1 to SLn_1, that from the first scan D-IC 440 are connected to the odd subpixels and the scan lines SL1_2 to SLn_2 that from the second scan D-IC 440 ' are connected to the even subpixels.

As described above, this is the pixel 414 formed in a vertical strip shape. In the case of a vertical stripe-like pixel, the R, G and B subpixels are 416 adjacent in the column direction and not angeorndet in the row direction.

Regarding 5 contains each of the subpixels 416 an electroluminescent (EL) cell connected between the voltage source VDD and a ground terminal GND and an EL drive circuit 418 for driving the EL cell to drive signals which are supplied from the data line DL and from the scan line SL.

The EL drive circuit 418 includes: a driving TFT DT connected between the power source VDD and the EL cell; a first switching TFT T1 which is connected to the scan line SL and to the data line DL; and a second switching TFT T2 who with the first Switching TFT T1 and the driving TFT DT; and a converter TFT MT connected between the voltage source VDD and a node of the first switching TFT T1 and the second switching TFT T2 is switched, the converter TFT MT forms together with the driving TFT DT a current mirror to convert a current to a voltage, and a storage capacitor cst is between the voltage source VDD and the gates of the driving TFT DT and the converter TFT MT connected.

The driving TFT DT has a gate connected to the gate of the converter TFT MT a source connected to the voltage source VDD and a drain connected to the EL cell. The converter TFT MT has a source connected to the voltage source VDD, a drain connected to the drain of the first switching TFT T1 is connected and a source connected to the second switching TFT T2 connected is. The first switching TFT T1 has a source connected to the data line DL and a drain connected to a source of the second switching TFT T2 connected is. The second switching TFT T2 has a drain connected to the gates of the drive TFT DT and the converter TFT MT and the storage capacitor Cst is connected. The first and second switching TFTs T1 and T2 have gates that are connected to the scan line scan. The first and second switching TFT T1 and T2 have gates connected to the scan line SL. The converter TFT MT and the driving TFT DT form a current mirror circuit because they are designed to have the same electrical characteristics. When the converter TFT MT and the driving TFT DT are formed identically, the amount of current passing through the transducer TFT MT flows, be identical to the amount of current passing through the driving TFT DT flows.

In this way, the EL display device according to the embodiments of the present invention guides each of the subpixels 416 a data signal proportional to input data with a current level or a pulse width. Each of the subpixels 416 emits light in proportion to a quantity of electricity or a pulse width coming from the data line DL is supplied. The flow control 460 generates a data control signal for controlling the data D-IC 430 and a scan control signal for controlling the Scan D-IC 440 by using synchronization signals supplied from an external system, such as a graphics card. Next arranges the flow control 460 converts a video data stream from an external system and carries data D-IC 430 a reordered video stream.

6 FIG. 12 shows a timing chart for signals applied to the EL display device according to an embodiment of the present invention. FIG. Here, it is assumed that the multiplexer unit operates in response to two multiple-bit clock signals, as in FIGS 4 and 5 shown. That is, it will be from the flow control 460 a first and a second selection signal MUX CLK1 and MUX CLK2 as two multiplexed clock signals to the multiplexer unit 450 supplied, wherein the first and second selection signal MUX CLK1 and MUX CLK2 have opposite polarities to each other.

Regarding 6 For example, the scan signals supplied to the EL display device according to an embodiment of the present invention are input sequentially. Further, the scan signals are divided into two, since there are two multiplexed clock signals. In one embodiment of the present invention, the 1_1 scan signal Scan1_1 and the 1_2 scan signal Scan1_2 supplied separately to the first subpixel line. A sum of the pulse widths of the 1_1 scan signal Scan1_1 and the 1_2 scan signal Scan1_2 corresponds to 1 / 6 multiplied by the pulse width of the scan signal Scanl according to the prior art. Thus, the period of the first conventional scan signal Scan1 is divided and is from the 1_1 scan signal Scan1_1 up to the 3_2 scan signal Scan3_2 busy. When the 1_1 scan signal Scan1_1 is on, is the first select signal MUX CLK1 also configured so that the odd subpixels on the first subpixel line are allowed to input their corresponding data. When the 1_1 scan signal Scan1_1 is off, is the first select signal MUX CLK1 also turned off.

When the 1_2 scan signal Scan1_2 is on, is the second selection signal MUX CLK2 is turned on so that the even subpixels on the first subpixel line are allowed to input their corresponding data. When the 1_2 scan signal Scan1_2 is off, is the second selection signal MUX CLK2 also turned off. In other words, the first select signal retains MUX CLK1 the on-state during 1 / 6 a horizontal period and the second selection signal MUX CLK2 retains the on state during 1 / 6 a horizontal period during which the first selection signal MUX CLK1 is off. Next have the 1_1 scan signal Scan1_1 up to the 3_2 scan signal Scan3_2 Scan pulses on the on-state during 1 / 6 maintain a horizontal period.

7 FIG. 12 is an illustration of formatting a data stream supplied to the EL display device according to an embodiment of the present invention. FIG. Here, it is assumed that the multiplexer unit operates on two multiplexed clock signals, the one color pixels forming red, green and blue subpixels are connected to the same data line DL, as in 4 and 5 shown. Thus, the video data stream applied to the sub-pixels on a line in the conventional EL display device becomes 6 Divided video data streams, similar to the scan signal.

7 shows a video data stream Din-one, the flow control 406 in a conventional EL display device according to an embodiment of the present invention. The input video data stream is from the sequencer 460 classified into red, green and blue subpixel data streams. The flow control 460 splits each of the red, green and blue subpixel data streams into even and odd subpixel data streams. Consequently, the input video data stream Din-one applied to the sub-pixels of a line in a conventional EL display device becomes the process control 460 in six subpixel streams Dscan1_1 to Dscan 3_2 rearranged, as in 7 shown. The subpixel data streams Dscan1_1 and Dscan1_2 contain corresponding odd red subpixel data and even red subpixel data. The subpixel data streams Dscan2_1 and Dscan2_2 contain corresponding odd green subpixel data and just green subpixel data. The subpixel data streams Dscan3_1 and Dscan2_3 contain correspondingly blue subpixel data and just blue subpixel data. The in the flow control 460 rearranged six subpixel streams Dscan1_1 to Dscan3_2 be the data D-IC 430 fed sequentially. In the conventional EL display device, the input video data stream Din-one becomes the data D-IC 20 via a sequence control 26 fed in the original format.

The data D-IC 430 supplies the j odd data lines DL1 to DLk 1 with the j data signals respectively corresponding to the j odd red subpixel data appearing in the subpixel data stream Dscan1_1 contained over the multiplexer unit 450 when the 1_1 scan signal Scan1_1 and the first selection signal MUX CLK1 are turned on. The j data signals, each of j straight red subpixel data in the subpixel data stream Dscan1_2 depend on the even data lines DL2 to DLk from the data D-IC 430 via the multiplexer unit 450 fed during the 1_2 scan signal Scan1_2 and the second selection signal MUX CLK2 are turned on. Likewise, each of odd green subpixel data in the subpixel data stream becomes Dscan2_1 dependent j data signals the odd data lines DL1 to DLk 1 from the data D-IC 430 via the multiplexer unit 450 supplied when the 2_1 scan signal Scan2_1 and the first selection signal MUX CLK1 are turned on. If the 2_2 scan signal Scan2_2 and the second selection signal MUX CLK2 are activated, the j data signals corresponding to the j even green subpixel data become the subpixel data stream Dscan2_2 the j straight data lines DL2 to DLk from the data D-IC 430 via the multiplexer unit 450 fed. In the period in which the 3_1 scan signal Scan3_1 and the first selection signal MUX CLK1 are activated, the j data signals corresponding to the j uneven blue subpixel data stream Dscan3_1 the odd data lines DL1 to DLk 1 from the data D-IC 430 via the multiplexer unit 450 fed. Finally, the j data signals from the j even blue subpixel data in the subpixel data stream become Dscan3_2 depend, even the j straight data lines DL2 to DLk from the data D-IC 430 via the multiplexer unit 450 supplied in the interval in which the 3_2 Scan signal Scan3_2 and the second execution signal MUX CLK2 are turned on.

Thus, in this embodiment, two multiple-bit clock signals are used and the scan lines are used six times more often than the prior art scan lines. As described above, the first selection signal becomes MUX CLK1 turned on while one of the 1_1 scan signals Scan1_1 until the n_1 scan signal ScanN_1 are turned on. Therefore, the data is fed to the odd subpixels. Then, when the first selection signal MUX CLK1 is off, is the scan signal turned off (that is, one of the 1_1 scan signals Scan1_1 up to the n_1 scan signal ScanN_1 ) also turned off. Consequently, the number of output channels OC1 to OCj of the data D-IC 430 be reduced. The 1_1 scan signal Scan1_1 until the n_1 scan signal ScanN_1 is connected to the odd subpixels and the 1_2 scan signal Scan1_2 until the n_2 scan signal Scann_2 is connected to the straight subpixels in an alternating way.

According to the embodiments of the present invention, a multiplexer unit in an EL display panel for a 1 : i adaptation of the output channels of the data D-IC formed on the data lines (where "i" is a positive integer greater than or equal 1 is). In addition, the pixels are connected to the odd and even scan lines in an alternating manner, the pixel part being formed as a vertical stripe-like pixel. Thus, the number of output channels of the data D-IC is at least 1 / 6 reduced, whereby a more compact EL display panel can be made.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present invention. For example, in the 4 and 5 the multiplexer unit 450 be omitted while each of the output channels OC1 to OCj of the data D-IC 430 may be connected to at least two of the data lines DL.

Claims (1)

A method of driving an electroluminescent display device (400) comprising: an electroluminescent display panel (410) having red, green and blue subpixels (416) in areas selected by a plurality of data lines (DL1-DLk) and a plurality of scan lines (Scan n_1, scan n_2), an integrated scan driver circuit (440, 440 ') for driving the scan lines (scan n_1, scan n_2) and an integrated data driver circuit (430) for driving the data lines (DL1-DLk) and a multiplexer unit (450) for selectively connecting output channels (OC1-OCj) of the integrated data driver circuit (430) to one of at least two of the data lines, the method comprising the steps of: - supplying selection signals of two multiplexed clock signals (MUX CLK1, MUX CLK2) to the multiplexer unit (450); - applying a first selection signal of the multiplexed clock signals (MUX CLK1, MUX CLK2) to connect output channels (OC1-OCj) of the integrated data driver circuit (430) to subpixels (416) connected to odd scan lines; and - applying a second selection signal of the multiplexed clock signals (MUX CLK1, MUX CLK2) to connect output channels (OC1-OCj) of the integrated data driver circuit (430) to subpixels (416) connected to straight scan lines, wherein each of the subpixels comprises an EL cell connected between a voltage source (Vdd) and a ground terminal (GND), wherein the first selection signal is turned on and off every 1/6 of a horizontal period, the second selection signal being switched to a state opposite to the first selection signal, wherein the red (R), green (G) and blue (B) subpixels (416) are arranged along the same data line, wherein the scan driver circuit (440, 440 ') includes a first scan integrated driver circuit (440) for driving a first set of scan lines (Scan1_1 to Scan n_1) and a second scan integrated drive circuit (440') for driving from a second set of scan lines (Scan1_2 to Scan n_2), wherein scan pulses maintaining their on-state during one-sixth of the horizontal period are applied sequentially to the scan lines (scan n_1, scan n_2), wherein a pair of scan lines (Scan1_1, Scan1_2) of the first and second integrated scan driver circuits (440, 440 ') are disposed adjacent to each other and the pair of scan lines (Scan1_1, Scan1_2) of the first and second integrated scan lines Driver circuit (440, 440 ') is alternately connected to the sub-pixels in the row direction, and wherein all sub-pixels in each row correspond to only one color of red, green or blue, so that the pair of scan lines (Scan1_1, Scan1_2) applies scan signals only to sub-pixels having the one color in the row.

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