Patent Publication Number: US-7903051-B2

Title: Electro-luminescence display device and driving method thereof

Description:
This application claims the benefit of Korean Patent Application No. 2003-83944, filed on Nov. 25, 2003, which is hereby incorporated by reference for all purposes as if fully set forth herein. 
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     This invention relates to an electro-luminescence display (ELD), and more particularly to an electro-luminescence display device with a high aperture ratio and a driving method thereof. 
     2. Discussion of the Related Art 
     Recently, various flat panel display devices have been developed with reduced weight and size that are capable of eliminating the disadvantages associated with a cathode ray tube (CRT). Such flat panel display devices include liquid crystal displays (LCD), field emission displays (FED), plasma display panels (PDP) and electro-luminescence (EL) panels. 
     The EL display in such display devices is a self-emission device in which a phosphorous material is excited using recombination of electrons and holes. The EL display device is generally classified into inorganic EL devices and organic EL devices, depending upon a source material for the light-emitting layer. The EL display has the same advantage as the CRT in that it has a faster response speed than passive-type light-emitting devices requiring a separate light source like the LCD. 
       FIG. 1  is a cross-sectional view showing a related art organic EL structure for explaining a light-emitting principle of the EL display device. 
     Referring to  FIG. 1 , the organic EL device includes an electron injection layer  4 , an electron carrier layer  6 , a light-emitting layer  8 , a hole carrier layer  10  and a hole injection layer  12  that are sequentially disposed between a cathode  2  and an anode  14 . 
     If a voltage is applied between a transparent electrode, that is, the anode  14  and a metal electrode, that is, the cathode  2 , then electrons produced from the cathode  2  are moved, via the electron injection layer  4  and the electron carrier layer  6 , into the light-emitting layer  8 , while holes produced from the anode  14  are moved, via the hole injection layer  12  and the hole carrier layer  10 , into the light-emitting layer  10 . Thus, the electrons and the holes fed from the electron carrier layer  6  and the hole carrier layer  10 , respectively, collide at the light-emitting layer  8  to be recombined to generate a light. This light is emitted, via the transparent electrode (i.e., the anode  14 ), into the exterior to thereby display a picture. 
       FIG. 2  shows a related art active matrix type EL display device. 
     Referring to  FIG. 2 , the related art active matrix type EL display device includes an EL display panel  16  having pixel (hereinafter referred briefly to as “PE”) cells  22  arranged at each intersection between gate electrode lines GL and data electrode lines DL, first and second gate drivers  18  and  19  for driving the gate electrode lines GL, and a data driver  20  for driving the data electrode lines DL. The first gate driver  18  sequentially applies a first gate signal to odd-numbered gate electrode lines GL 1 , GL 3 , . . . GLn−1. The second gate driver  19  sequentially applies a second gate signal to even-numbered gate electrode lines GL 2 , GL 4 , . . . GLn. Herein, the first and second gate signals are set to have the same width (e.g., 1H), and are applied in such a manner to overlap with each other during a predetermined period. 
     The data driver  20  applies video signals corresponding to a data, via the data electrode lines DL, to the PE cells  22 . In this case, the data driver  20  applies the video signals for each one horizontal line to the data electrode lines DL every one horizontal period when the first and second gate signals are supplied. 
     The PE cells  22  generate a light corresponding to the video signals (i.e., current signals) applied to the data electrode lines DL to thereby display a picture corresponding to the video signals. To this end, as shown in  FIG. 3 , each PE cell  22  includes a light-emitting cell driving circuit  30  for driving a light-emitting cell OLED in response to a driving signal supplied from each of the data electrode lines DL and the gate electrode lines GL, and a light-emitting cell OLED connected between the light-emitting cell driving circuit  30  and the ground voltage source GND. 
     The light-emitting cell driving circuit  30  includes a first driving thin film transistor (TFT) T 1  connected between the supply voltage line VDD and the light-emitting cell OELD, a first switching TFT T 3  connected between the odd-numbered gate electrode line GLo and the data electrode line DL, a second switching TFT T 4  connected between the first switching TFT T 3  and the even-numbered gate electrode line GL, a second driving TFT T 2  connected between a node positioned between the first and second switching TFTs T 3  and T 4  and the supply voltage line VDD to form a current mirror circuit with respect to the driving TFT T 1 , and a storage capacitor Cst connected between a node positioned between the first and second driving TFTs T 1  and T 2  and the supply voltage line VDD. Herein, the TFT is a p-type electron metal-oxide semiconductor field effect transistor (MOSFET). 
     A gate terminal of the driving TFT T 1  is connected to the gate terminal of the second driving TFT T 2 ; a source terminal thereof is connected to the supply voltage line VDD; and a drain terminal thereof is connected to the light-emitting cell OLED. A source terminal of the second driving TFT T 2  is connected to the supply voltage line VDD, and a drain terminal thereof is connected to a drain terminal of the first switching TFT T 3  and a source terminal of the second switching TFT T 4 . 
     A source terminal of the first switching TFT T 3  is connected to the data electrode line DL, and a gate terminal thereof is connected to the odd-numbered gate electrode line GLo. A drain terminal of the second switching TFT T 4  is connected to the gate terminals of the first and second driving TFTs T 1  and T 2  and the storage capacitor Cst. A gate terminal of the second switching TFT T 4  is connected to the even-numbered gate electrode line GLe. 
     Herein, the first and second driving TFTs T 1  and T 2  are connected to each other in such a manner to form a current mirror. Thus, assuming that the first and second driving TFTs T 1  and T 2  have the same channel width, a current amount flowing in the first driving TFT T 1  is set to be equal to a current flowing in the second driving TFT T 2 . 
     An operation procedure of such a light-emitting cell driving circuit  30  will be described in detail with reference to a driving waveform of  FIG. 4  below. 
     First and second gate signals SP 1  and SP 2  having the same width are applied to the odd-numbered electrode line GLo and the even-numbered electrode line GLe making the same horizontal line, respectively, in such a manner to overlap with each other during a predetermined period. Herein, the second gate signal SP 2  is applied prior to the first gate signal SP 1 . 
     If the first and second gate signals SP 1  and SP 2  are supplied, then the first and second switching TFTs T 3  and T 4  are turned on. As the first and second switching TFTs T 3  and T 4  are turned on, a video signal from the data electrode line DL is applied, via the first and second switching TFTs T 3  and T 4 , to the gate terminals of the first and second driving TFTs T 1  and T 2 . At this time, the first and second driving TFTs T 1  and T 2  supplied with the video signal are turned on. Herein, the first driving TFT T 1  controls a current flowing from the source terminal thereof (i.e., VDD) into the drain terminal thereof in response to the video signal applied to the gate terminal thereof to apply it to the light-emitting cell OLED, thereby allowing the light-emitting cell OLED to emit an amount of light corresponding to the video signal. 
     At the same time, the second driving TFT T 2  applies a current id fed from the supply voltage line VDD, via the first switching TFT T 3 , to the data electrode line DL. Herein, since the first and second driving TFTs T 1  and T 2  form a current mirror circuit, the same current flows in the first and second driving TFTs T 1  and T 2 . Meanwhile, the storage capacitor Cst stores a voltage from the supply voltage line VDD in such a manner to correspond to an amount of the current id flowing into the second driving TFT T 2 . Further, the storage capacitor Cst turns on the first driving TFT T 1  using a voltage stored therein when the first and second gate signals SP 1  and SP 2  are inverted into OFF signals (e.g., ground potentials) to turn off the first and second switching TFTs T 3  and T 4 , thereby applying a current corresponding to the video signal to the light-emitting cell OEL. On the other hand, since the second gate signal SP 2  is inverted into an OFF signal earlier than SP 1 , that is, the second switching TFT T 4  is turned off prior to the first switching TFT T 3  in the prior art, it is possible to prevent a voltage charged in the storage capacitor Cst from being discharged into the exterior. 
     In practice, the conventional EL display device sequentially applies the first and second gate signals SP 1  and SP 2  to the odd-numbered and even-numbered gate electrode lines GLo and GLe, respectively, and applies video signals to the data electrode lines DL, thereby displaying a desired picture. However, such a conventional EL display device has a problem in that, since driving a single of light-emitting cell OELD requires two gate electrode lines at a single of horizontal line and four TFTs, aperture ratio is low. Moreover, such a conventional EL display device has two gate drivers to drive the odd-numbered gate electrode lines GLo and the even-numbered electrode lines GLe, leading to high manufacturing cost. 
     SUMMARY OF THE INVENTION 
     Accordingly, the present invention is directed to an electro-luminescence display device and a driving method thereof that substantially obviates one or more of the problems due to limitations and disadvantages of the related art. 
     An advantage of the present invention is to provide an electro-luminescence display device with a high aperture ratio and a driving method thereof. 
     Additional features and advantages of the invention will be set forth in the description which follows, and in part will be apparent from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings. 
     To achieve these and other advantages and in accordance with the purpose of the present invention, as embodied and broadly described, an electro-luminescence display device may, for example, include a plurality of pixels arranged in a matrix type; a plurality of data lines for applying video signals to the pixels; and a plurality of gate lines crossing the data lines, one of the gate lines connected to the pixels positioned adjacently to each other at the upper and lower sides of the gate line. 
     The electro-luminescence display device further includes a gate driver for applying a gate signal having a turn-on potential during two horizontal periods to the gate lines. 
     Herein, a gate signal applied to the ith gate line (wherein i is an integer) overlaps a gate signal applied to the (i+1)th gate line during one horizontal period. 
     In anther aspect of the present invention, an electro-luminescence display device may, for example, include electro-luminescence cells arranged in a matrix type at crossings of gate lines and data lines; a supply voltage line for supplying a driving voltage to the electro-luminescence cells; driving circuits for controlling a current applied from the driving voltage of the supply voltage line to the electro-luminescence cells in response to video signals; and control circuits for applying the video signals to the driving circuits. 
     In the electro-luminescence display device, each of the driving circuits includes a first driving circuit provided at the ith horizontal line (wherein i is an integer) to apply the current to the electro-luminescence cell positioned at the ith horizontal line, in response to a video signal from the control circuit controlled by the ith gate line, when a gate signal is applied to the (i−1)th gate line; and a second driving circuit provided at the (i+1)th horizontal line to apply the current to the electro-luminescence cell positioned at the (i+1)th horizontal line, in response to a video signal from the control circuit controlled by the ith gate line, when a gate signal is applied to the (i+1)th gate line. 
     Herein, the control circuit is positioned between the first driving circuit and the second driving circuit. 
     The second driving circuit provided at the (i−1)th horizontal line is connected to the (i−1)th gate line. 
     The first driving circuit provided at the (i+2)th horizontal line is connected to the (i+1)th gate line. 
     The first driving circuits includes a first driving thin film transistor having a source terminal connected to the supply voltage line and a drain terminal connected to the electro-luminescence cell positioned at the ith horizontal line; a second driving thin film transistor having a drain terminal connected to a gate terminal of the first driving thin film transistor, a source terminal connected to the control circuit and a gate terminal connected to the (i−1)th gate line; and a storage capacitor connected between the source terminal and the gate terminal of the first driving thin film transistor. 
     The second driving circuits includes a first driving thin film transistor having a source terminal connected to the supply voltage line and a drain terminal connected to the electro-luminescence cell positioned at the (i+1)th horizontal line; a second driving thin film transistor having a drain terminal connected to a gate terminal of the first driving thin film transistor, a source terminal connected to the control circuit and a gate terminal connected to the (i+1)th gate line; and a storage capacitor connected between the source terminal and the gate terminal of the first driving thin film transistor. 
     The control circuit includes a first control thin film transistor having a source terminal connected to the supply voltage line and a drain terminal and a gate terminal connected to the source terminal of the second driving thin film transistor; and a second control thin film transistor having a drain terminal connected to the gate terminal of the first control thin film transistor, a source terminal connected to the data line and a gate terminal connected to the ith gate line. 
     Herein, any one of the first and second control thin film transistors is provided at the ith horizontal line while the remaining control thin film transistor is provided at the (i+1) the horizontal line. 
     The electro-luminescence display device further includes a gate driver for applying a gate signal having a turn-on potential during two horizontal periods to the gate lines. 
     Herein, a gate signal applied to the ith gate line overlaps a gate signal applied to the (i+1)th gate line during one horizontal period. 
     If a gate signal is applied to the (i−1)th and ith gate lines, then the second driving thin film transistor connected to the (i−1)th gate line and the second control thin film transistor connected to the ith gate line are turned on; and, as the second control thin film transistor is turned on, a video signal from the data line is applied to the first driving thin film transistor and the first control thin film transistor that are positioned at the ith horizontal line. 
     Herein, the first driving thin film transistor positioned at the ith horizontal line applies the current corresponding to the video signal to the electro-luminescence cell provided at the ith horizontal line. 
     The first control thin film transistor applies the current corresponding to the video signal from the supply voltage line to the data line. 
     Herein, a voltage corresponding to the current flowing in the first control thin film transistor is stored in the storage capacitor. 
     In still another aspect of the present invention, an electro-luminescence display device may, for example, include a plurality of pixels arranged in a matrix type; a plurality of data lines for applying video signals to the pixels; a plurality of gate lines crossing the data lines, one of the gate lines being shared with the pixels positioned adjacently to each other at the upper and lower sides of the gate line; electro-luminescence cells provided for each pixel; a supply voltage line for supplying a driving voltage to the electro-luminescence cells; driving circuits for applying a current corresponding to the video signals to the electro-luminescence cells in response to the video signals; and control circuits connected to the data lines to apply the video signals supplied to the data lines to the driving circuits. 
     The electro-luminescence display device further includes a gate driver for applying a gate signal having a turn-on potential during two horizontal periods to the gate lines. 
     Herein, a gate signal applied to the ith gate line (wherein i is an integer) overlaps a gate signal applied to the (i+1)th gate line during one horizontal period. 
     Each of the driving circuits includes a first driving circuit provided at the ith horizontal line (wherein i is an integer) to apply the current to the electro-luminescence cell positioned at the ith horizontal line, in response to a video signal from the control circuit controlled by the ith gate line, when a gate signal is applied to the (i−1)th gate line; and a second driving circuit provided at the (i+1)th horizontal line to apply the current to the electro-luminescence cell positioned at the (i+1)th horizontal line, in response to a video signal from the control circuit controlled by the ith gate line, when a gate signal is applied to the (i+1)th gate line. 
     Herein, the control circuit is positioned between the first driving circuit and the second driving circuit. 
     In yet another aspect of the present invention, a method of driving an electro-luminescence display device may, for example, include applying a gate signal having a turn-on potential during two horizontal periods to gate lines, wherein the gate signal applied to the ith gate line (wherein i is an integer) overlaps the gate signal applied to the (i−1)th gate line during one horizontal period. 
     In the method, a current corresponding to a video signal is applied to an electro-luminescence cell provided at the ith horizontal line during the one horizontal period in which the gate signal applied to the (i−1)th gate line overlaps with the gate signal applied to the ith gate line. 
     In another aspect of the present invention, a flat panel display device may, for example, include a plurality of gate lines including N−1th, Nth and N+1th gate lines, wherein N is an integer and greater than 1; a plurality of data lines crossing the gate lines; and first, second and third driving blocks, each block being electrically connected with at least one of the data lines and at least one of the gate lines, wherein each block includes first and second driving circuits, and a control circuit; wherein the N−1 th gate line is electrically connected with the first driving circuit of the second driving block and the second driving circuit of the first driving block, the Nth gate line is electrically connected with the control circuit of the second driving block, and N+1th gate line is electrically connected with the second driving circuit of the second driving block and the first driving circuit of the third driving block. 
     It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention. 
       In the drawings: 
         FIG. 1  is a schematic cross-sectional view showing a structure of an organic light-emitting cell in a related art electro-luminescence display panel; 
         FIG. 2  is a block diagram showing a configuration of a related art electro-luminescence display panel; 
         FIG. 3  is an equivalent circuit diagram of each pixel cell PE shown in  FIG. 2 ; 
         FIG. 4  is a waveform diagram of the gate signals applied to the gate lines shown in  FIG. 2 ; 
         FIG. 5  is a block diagram showing a configuration of an electro-luminescence display device according to an embodiment of the present invention; 
         FIG. 6  is an equivalent circuit diagram of each pixel cell PE shown in  FIG. 5 ; and 
         FIG. 7  is a waveform diagram of the gate signals applied to the gate lines shown in  FIG. 5 . 
     
    
    
     DETAILED DESCRIPTION OF THE ILLUSTRATED EMBODIMENTS 
     Reference will now be made in detail to an embodiment of the present invention, example of which is illustrated in the accompanying drawings. 
       FIG. 5  shows an active matrix type electro-luminescence (EL) display device according to an embodiment of the present invention. 
     Referring to  FIG. 5 , the EL display device includes an EL display panel  40  having pixel (hereinafter referred briefly to as “PE”) cells  46  arranged at each intersection between gate electrode lines GL and data electrode lines DL, a gate driver  44  for driving the gate electrode lines GL, and a data driver  42  for driving the data electrode lines DL. 
     The gate electrode lines GL are connected to the PE cells  46  positioned at the upper/lower portions thereof. In other words, the ith gate electrode line GLi (wherein i is an integer) is connected to both the PE cells  46  provided at the ith horizontal line and the PE cells  46  provided at the (i+1)th horizontal line. Herein, the ith gate electrode line GLi drives the PE cells  46  provided at the ith and (i+1)th horizontal lines. In other words, the embodiment of the present invention allows a single gate electrode line GL to drive the PE cells  46  positioned adjacently to each other at the upper/lower portions thereof. Thus, this embodiment of the present invention can reduce a number of gate electrode lines GL by half (½) in comparison to the related art, and hence can assure a high aperture ratio. Furthermore, due to the reduced number of gate electrode lines GL, it is possible to drive the EL display device using a single gate driver  44  and to reduce manufacturing cost. 
     As shown in  FIG. 7 , the gate driver sequentially applies a gate signal having a turn-on potential during two horizontal periods (2H) to the gate electrode lines GL. Herein, a gate signal applied to the ith gate electrode line GLi overlaps with a gate signal applied to the (i−1)th gate electrode line GLi−1 during one horizontal period (1H). 
     The data driver  42  applies video signals corresponding to a data, via the data electrode lines DL, to the PE cells  46 . Herein, the data driver  42  applies video signals for each one horizontal line to the data electrode lines DL every one horizontal period (1H). 
     The PE cells  46  emit a light corresponding to the video signals (i.e., current signals) applied to the data electrode lines DL to thereby display a picture. To this end, the PE cells  46  are configured as shown in  FIG. 6 . 
     Referring to  FIG. 6 , the PE cells  46  according to an embodiment of the present invention includes driving circuits  50  for driving the light-emitting cells OLED, and a control circuit  52  for controlling the driving circuits  50  positioned adjacently to each other at the upper/lower portions thereof. Herein, two driving circuits  50  positioned adjacently to each other at the upper/lower portions thereof makes a pair  100  and  102  (hereinafter referred to “driving circuit pair”) to be controlled by a single control circuit  52 . The control circuit  52  controls two driving circuits  50  under control of a single gate electrode line GL connected thereto. 
     The driving circuits  50  are configured such that a current can be applied to each light-emitting cell OLED arranged in a matrix type. The control circuit  52  is provided between the driving circuit pairs  100  and  102  to thereby control the driving circuits  50  positioned adjacently to each other at the upper/lower portions thereof. Herein, the control circuit  52  is provided for each driving circuit pair  100  and  102 , so that the number of control circuits  52  included in one vertical line is set to be a half of the number of driving circuits  50 . 
     On the other hand, the driving circuits  50  positioned adjacently to each other at the upper/lower portions thereof and not provided with the control circuit  52  therebetween are connected to the same gate electrode line. For instance, if the driving circuits  50  provided at the ith and (i+1)th horizontal lines make a driving circuit pair  100  and the driving circuits  50  provided at the (i+2)th and (i+3)th horizontal lines make a driving circuit pair  102 , the driving circuits  50  positioned at the (i+1)th horizontal line and the (i+2)th horizontal line are connected to the same gate electrode line. 
     The driving circuit  50  provided for each light-emitting cell OLED has two TFTs T 1  and T 2 . For instance, each driving circuit  50  includes a first driving TFT T 1  provided between the light-emitting cell OLED and the supply voltage line VDD, and a second driving TFT T 2  provided between the first driving TFT T 1  and the gate electrode line GL. 
     Herein, the gate terminal of the second driving TFT T 2  included in the first driving circuit  50  of the driving circuit pair  100 , for example, the driving circuit  50  provided at the ith horizontal period, is connected to the (i−1) the gate electrode line GLi−1 (wherein, the (i−1)th gate electrode line GLi−1 is also connected to the second driving TFT T 2  of the driving circuit  50  provided at the (i−1)th horizontal line), and the source terminal thereof is connected to the control circuit  52  located adjacently. The gate terminal of the first driving TFT T 1  included in the driving circuit  50  provided at the ith horizontal line is connected to the drain terminal of the second driving TFT T 2 , and the source terminal thereof is connected to the supply voltage line VDD. Further, the drain terminal of the first driving TFT T 1  is connected to the light-emitting cell OLED 1 . The storage capacitor Cst is connected between the source terminal and the gate terminal of the first driving TFT T 1 . 
     On the other hand, the gate terminal of the second driving TFT T 2  included in the second driving circuit  50  of the driving circuit pair  100 , for example, the driving circuit  50  provided at the (i+1)th horizontal period, is connected to the (i+1) the gate electrode line GLi+1 (wherein, the (i+1)th gate electrode line GLi+1 is also connected to the second driving TFT T 2  of the driving circuit  50  provided at the (i+2)th horizontal line), and the source terminal thereof is connected to the control circuit  52  located adjacently. The gate terminal of the first driving TFT T 1  included in the driving circuit  50  provided at the (i+1)th horizontal line is connected to the drain terminal of the second driving TFT T 2 , and the source terminal thereof is connected to the supply voltage line VDD. Further, the drain terminal of the first driving TFT T 1  is connected to the light-emitting cell OLED. The storage capacitor Cst is connected between the source terminal and the gate terminal of the first driving TFT T 1 . The first and second driving TFTs T 1  and T 2  included in the driving circuit pairs  100  and  102  are provided for each light-emitting cell OLED in this manner. 
     The control circuit  52  provided between the driving circuit pair  100 , for example, the control circuit  52  positioned between the ith and (i+1)th horizontal lines includes a first control TFT T 3  and a second control TFT T 4 . Herein, two TFTs T 3  and T 4  included in the control circuit  52  are provided in such a manner to be located at different horizontal lines. For instance, the first control TFT T 3  is provided to be located at the ith horizontal line, while the second control TFT T 4  is provided to be located at the (i+1)th horizontal line. Alternatively, the first control TFT T 3  may be provided to be located at the (i+1)th horizontal line, while the second control TFT T 4  may be provided to be located at the ith horizontal line. 
     The source terminal of the first control TFT T 3  is connected to the supply voltage line VDD, and the drain terminal and the gate terminal thereof are connected to the second driving TFT T 2  included in the driving circuits  50  positioned at the upper/lower portions thereof. The source terminal of the second control TFT T 4  is connected to the data line DL; the drain terminal thereof is connected to the drain terminal and the gate terminal of the first control TFT T 3 ; and the gate terminal thereof is connected to the ith gate electrode line GLi. 
     An operation procedure of the PE cells  46  according to the embodiment of the present invention will be described in detail with reference to a driving waveform of  FIG. 7  below. 
     First, a gate signal is applied to the (i−1)th gate electrode line GLi−1. Then, another gate signal overlapping with the gate signal supplied to the (i−1)th gate electrode line GLi−1 during one horizontal period (1H) is applied to the ith gate electrode line GLi. As a gate signal is applied to the (i−1)th gate electrode line GLi−1, the second driving TFT T 2  positioned at the ith horizontal line is turned on. Further, as a gate signal is applied to the ith gate electrode line GLi, the second control TFT T 4  connected to the ith gate electrode line GLi is turned on. As the second control TFT T 4  and the second driving TFT T 2  are turned on, a video signal from the data electrode line DL is applied to the gate terminals of the first control TFT T 3  and the first driving TFT T 1 . At this time, the first control TFT T 3  and the first driving TFT T 1  supplied with the video signal are turned on. 
     Herein, the first driving TFT T 1  controls a current flowing from the source terminal thereof (i.e., VDD) into the drain terminal thereof in response to the video signal applied to the gate terminal thereof to apply it to the light-emitting cell OLED, thereby allowing the light-emitting cell OLED  1  to emit an amount of light corresponding to the video signal. At the same time, the first control TFT T 3  applies a current fed from the supply voltage line VDD, via the second control TFT T 4 , to the data electrode line DL. Meanwhile, the storage capacitor Cst stores a voltage from the supply voltage line VDD in such a manner to correspond to an amount of the current flowing in the first control TFT T 3 . Further, the storage capacitor Cst turns on the first driving TFT T 1  using a voltage stored therein when the video signal is not applied, thereby applying a current corresponding to the video signal to the light-emitting cell OLED 1 . 
     Thereafter, another gate signal is applied to the (i+1)th gate electrode line GLi+1 in such a manner to overlap with the gate signal applied to the ith gate electrode line GLi. As a gate signal is applied to the (i+1)th gate electrode line GLi+1, the second driving TFT T 2  positioned at the (i+1)th horizontal line and the second driving TFT T 2  positioned at the (i+2)th horizontal line are turned on. As the second driving TFT T 2  positioned at the (i+1)th horizontal line is turned on, a video signal from the data electrode line DL is applied, via the second driving TFT T 2  positioned at the (i+1)th horizontal line, to the gate terminal of the first driving TFT T 1 , thereby turning on the first driving TFT T 1 . 
     At this time, the first driving TFT T 1  positioned at the (i+1)th horizontal line controls a current flowing from the source terminal thereof (i.e., VDD) into the drain terminal thereof in response to the video signal applied to the gate terminal thereof to apply it to the light-emitting cell OLED, thereby allowing the light-emitting cell OLED 2  to emit an amount of light corresponding to the video signal. At the same time, the first control TFT T 3  applies a current fed from the supply voltage line VDD that becomes different in accordance with a video signal, via the second control TFT T 4 , to the data electrode line DL. Meanwhile, the storage capacitor Cst stores a voltage from the supply voltage line VDD in such a manner to correspond to an amount of the current flowing in the first control TFT T 3 . Further, the storage capacitor Cst turns on the first driving TFT T 1  using a voltage stored therein when the video signal is not applied, thereby applying a current corresponding to the video signal to the light-emitting cell OLED 2 . 
     Meanwhile, although a gate signal applied to the (i+1) the gate electrode line Gli+1 turns on the second driving TFT T 2  positioned at the (i+2)th horizontal line, a video signal fails to reach the light-emitting cell OLED 3  positioned at the (i+2)th horizontal line, because the second control TFT T 4  positioned between the driving circuit pair  102  is turned off. Thus light is not emitted from the light-emitting cell OLED 3  positioned at the (i+2)th horizontal line at this time. 
     Hereinafter, another gate signal is applied to the (i+2)th gate electrode line GLi+2 in such a manner to overlap with the gate signal applied to the (i+1)th gate electrode line Gli+1. As a gate signal is applied to the (i+2)th gate electrode line Gli+2, the second control TFT T 4  connected to the (i+2)th gate electrode line Gli+2 is turned on. As the second control TFT T 4  is turned on, a video signal from the data electrode line DL turns on the first control TFT T 3  connected to the second control TFT T 4  and the first driving TFT T 1  positioned at the (i+2)th horizontal line. 
     At this time, the first driving TFT T 1  positioned at the (i+2)th horizontal line controls a current flowing from the source terminal thereof (i.e., VDD) into the drain terminal thereof in response to the video signal applied to the gate terminal thereof to apply it to the light-emitting cell OLED 3 , thereby allowing the light-emitting cell OLED 3  to emit an amount of light corresponding to the video signal. At the same time, the first control TFT T 3  applies a current fed from the supply voltage line VDD, via the second control TFT T 4 , to the data electrode line DL. Meanwhile, the storage capacitor Cst stores a voltage from the supply voltage line VDD in such a manner to correspond to an amount of the current flowing in the first control TFT T 3 . Further, the storage capacitor Cst turns on the first driving TFT T 1  using a voltage stored therein when the video signal is not applied, thereby applying a current corresponding to the video signal to the light-emitting cell OLED 3 . In practice, the present EL display device repeats the above-mentioned procedure, thereby displaying a desired picture. 
     Such an EL display device provides a single control circuit between the driving circuit pair positioned adjacently to each other at the upper/lower portions thereof and controls the driving circuit positioned at the upper/lower sides, while controlling the control circuit by a single gate electrode line, so that it can reduce a number of gate electrode lines. In other words, since the driving circuit provided at the upper side of the driving circuit pair is connected to the same gate electrode line as the driving circuit provided at the previous horizontal line while the driving circuit provided at the lower side of the driving circuit pair is connected to the same gate electrode line as the driving circuit provided at the next horizontal line, it becomes possible to minimize the number of gate electrode line and thus to improve an aperture ratio. Furthermore, three TFTs (i.e., two at the driving circuit plus one at the control circuit) are provided for each light-emitting cell arranged in a matrix type, it becomes possible to more improve an aperture ratio. 
     As described above, according to the present invention, the gate electrode lines control the pixel cells positioned at the upper/lower sides, so that it becomes possible to reduce a number of gate lines and thus to improve an aperture ratio. Furthermore, according to the present invention, three TFTs are included for each pixel cell, so that it becomes possible to more improve an aperture ratio in comparison to the prior art. Moreover, according to the present invention, a number of gate electrode lines are reduced, so that it becomes possible to apply a gate signal to all the gate electrode lines using a single gate driver and thus to reduce manufacturing cost. 
     It will be apparent to those skilled in the art that various modifications and variation can be made in the present invention without departing from the spirit or scope of the invention. Thus, it is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.