KR100681029B1 - Electro-luminescence display - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electro-luminescence display device capable of shortening process time and reducing manufacturing costs.

The electro-luminescence display device of the present invention comprises: a gamma generator for outputting a reference gamma voltage corresponding to control data supplied from the outside; At least one data integrated circuit for receiving data from the outside and generating a data signal corresponding to the number of data bits using the reference gamma voltage is provided.

Description

Electro-Luminescence Display Apparatus}             

1 is a cross-sectional view showing the structure of a general organic electro-luminescence.

2A and 2B show a conventional electro-luminescence display.

3 is a circuit diagram illustrating a structure of a gamma voltage supply unit shown in FIGS. 2A and 2B.

4 is a detailed view of the data integrated circuit shown in FIGS. 2A and 2B.

FIG. 5 is a diagram illustrating an installation of a gamma voltage supply unit and a data integrated circuit shown in FIGS. 2A and 2B.

Fig. 6 is a diagram showing an electroluminescent display device according to a first embodiment of the present invention.

7A to 7C are views illustrating a structure of the gamma generator shown in FIG. 6.

FIG. 8 is a diagram illustrating an installation of a gamma generator and a data integrated circuit shown in FIG. 6.

Fig. 9 is a diagram showing an electroluminescent display device according to a second embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

2: cathode 4: electron injection layer

6: electron transport layer 8: light emitting layer

10 hole transport layer 12 hole injection layer

14: anode 20,60: display panel

22,62: scan driver 24,64: data driver

26: gamma voltage supply unit 28,70: cell

30,66,200: integrated circuit 40: shift register

42, 44: latch array 42a, 42b, 42c, 44a, 44b, 44c: latch portion

46,46a, 46b, 46c, 84,86,200a, 200b, 200c: DAC part

48: output array 48a, 48b, 48c: output

50,102: COF 52: FPC

68R, 68G, 68B, 100 Gamma generator 80,82 Resistance unit

88: register

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electroluminescent display device, and more particularly, to an electroluminescent display device capable of shortening process time and reducing manufacturing cost.

Recently, various flat panel display devices that can reduce weight and volume, which are disadvantages of cathode ray tubes, have emerged. Such flat panel displays include a liquid crystal display, a field emission display, a plasma display panel, and an electro-luminescence (hereinafter, EL). And a display device.

Among them, an EL display device is a self-luminous element that emits a phosphor by recombination of electrons and holes, and is classified roughly into an inorganic EL using an inorganic compound and an organic EL using an organic compound as the phosphor. Such an EL display device has an advantage that the response speed is as fast as that of a cathode ray tube as compared to a passive light emitting device requiring a separate light source like a liquid crystal display device. In addition, EL displays have many advantages such as low voltage driving, self-luminous, thin film type, wide viewing angle, fast response speed, high contrast, and the like, and are expected to be the next generation display devices.

1 is a cross-sectional view showing a general organic EL structure for explaining the light emission principle of an EL display device. The organic EL includes an electron injection layer 4, an electron transport layer 6, a light emitting layer 8, a hole transport layer 10, and a hole injection layer 12 stacked between the cathode 2 and the anode 14.

When a voltage is applied between the anode 14, which is a transparent electrode, and the cathode 2, which is a metal electrode, electrons generated from the cathode 2 are directed toward the light emitting layer 8 through the electron injection layer 4 and the electron transport layer 6. Move. In addition, holes generated from the anode 14 move toward the light emitting layer 8 through the hole injection layer 12 and the hole transport layer 10. Accordingly, in the light emitting layer 8, light is generated by collision between electrons and holes supplied from the electron transport layer 6 and the hole transport layer 10 and recombination, and the light is externally transmitted through the anode 14 which is a transparent electrode. Is emitted so that the image is displayed. The luminescence brightness of such an EL organic element is not proportional to the voltage across the element but proportional to the supply current, so that the anode 14 is usually connected to a constant current source.

2A is a diagram showing a general EL display device.

The EL display device illustrated in FIG. 2A includes an EL display panel 20 including EL cells 28 arranged at each intersection of the scan electrode line SL and the data electrode line DL, and the scan electrode lines SL. A scan driver 22 for driving the?, A data driver 24 for driving the data electrode lines DL, and a gamma voltage supply 26 for supplying reference gamma voltages to the data driver 24; do.

Each of the EL cells 28 is selected when a scan pulse is applied to the scan electrode line SL, which is a cathode, and corresponds to a pixel signal (ie, a data signal), that is, a current signal supplied to the data electrode line DL, which is a cathode. Will generate light. Each of the EL cells 28 is represented by a diode equivalently connected between the data electrode line DL and the scan electrode line SL. Each of the EL cells 28 is supplied with a negative scan pulse to the scan electrode line SL and emits light when a positive current is applied to the data electrode line DL and a forward voltage is applied thereto. On the contrary, the reverse direction voltage is applied to the EL cells 28 included in the unselected scan lines so as not to emit light.

The scan driver 22 sequentially supplies negative scan pulses to the plurality of scan electrode lines SL.

The data driver 24 includes at least one data integrated circuit 30. In fact, when the EL display panel 20 is a large inch, the data driver 24 includes at least two or more data integrated circuits 30 as shown in Fig. 2A. However, in the case where the EL display panel 20 is small in size (most of the EL display panels 20 are currently used in small inches, such as a portable telephone), as shown in FIG. 2B, one data integrated circuit is included in the data driver 24. 30).

The data integrated circuit 30 converts the digital data signal input from the outside into an analog data signal using the reference gamma voltage from the gamma voltage supply unit 26. The data integrated circuits 30 supply an analog data signal to the data lines DL every time a scan pulse is supplied. The detailed configuration of such data integrated circuit 30 will be described later.

In this manner, the conventional EL display device displays an image by supplying a current signal proportional to the input data to each of the EL cells 28 and causing the EL cells 28 to emit light. In addition, the EL cells 28 are R cells having a red (hereinafter referred to as R) phosphor, G cells having a green (hereinafter referred to as G) phosphor, and blue (hereinafter referred to as B) for color implementation. It consists of B cells which have a phosphor. In addition, three R, G, and B cells are combined to implement a color for one pixel. Here, each of the R, G, and B phosphors has different luminous efficiency. In other words, when a data signal having the same level is supplied to the R, G, and B cells, the luminance levels of the R, G, and B cells are different. Accordingly, for the white balance of the R, G, and B cells, gamma voltages of the same luminance are set differently for each of the R, G, and B cells. Therefore, the gamma voltage generator 26 supplying the reference gamma voltages to the data driver 24 generates different reference gamma voltages for each of R, G, and B.

FIG. 3 is a circuit diagram illustrating the gamma voltage supply unit 26 shown in FIGS. 2A and 2B in detail.

Referring to FIG. 3, the conventional gamma voltage supply unit 26 supplies an R gamma voltage generator 32, a G gamma voltage generator 34, and a B to supply different reference gamma voltages for respective R, G, and B cells. A gamma voltage generator 36 is provided.

The R gamma voltage generator 32 includes voltage dividers r_R1, r_R2, and r_R3 connected in series between the supply voltage source VDD and the ground voltage source GND. Here, the voltages (voltages applied to the n1 and n2) divided from the divided resistors r_R1, r_R2 and r_R3 are supplied to the data driver 24 as the reference gamma voltage. At this time, the voltage applied to the first node n1 is used as the R gamma voltage VH_R of low gray level, and the voltage applied to the second node n2 is used as the R gamma voltage VL_R of high gray level.

The G gamma voltage generator 34 includes voltage dividers r_G1, r_G2, and r_G3 connected in series between the supply voltage source VDD and the ground voltage source GND. Here, voltages (voltages applied to n3 and n4) divided from the divided resistors r_G1, r_G2, and r_G3 are supplied to the data driver 24 as the reference gamma voltage. At this time, the voltage applied to the third node n3 is used as the G gamma voltage VH_G of low gray level, and the voltage applied to the fourth node n4 is used as the G gamma voltage VL_G of high gray level.

The B gamma voltage generator 36 includes voltage dividers r_B1, r_B2, and r_B3 connected in series between the supply voltage source VDD and the ground voltage source GND. Here, voltages (voltages applied to n5 and n6) divided from the divided resistors r_B1, r_B2 and r_B3 are supplied to the data driver 24 as reference gamma voltages. At this time, the voltage applied to the fifth node n5 is used as the B gamma voltage VH_B of low gray level, and the voltage applied to the sixth node n6 is used as the B gamma voltage VL_B of high gray level.

That is, the conventional gamma voltage supply unit 26 supplies a reference gamma voltage corresponding to each of the R cells, the G cells, and the B cells to the data driver 24 to adjust the white balance of the R cells, the G cells, and the B cells. Meanwhile, the gamma voltage supply unit 26 generates an R gamma voltage generator 32, a G gamma voltage generator 34, and a B gamma voltage as shown in FIG. 3 so that light having different luminance may be generated in response to an external environment. It is provided with many parts 36. For example, the gamma voltage supply unit 26 may include an R gamma voltage generator 32, a G gamma voltage generator 34, and the like, so that reference gamma voltages of three modes may be supplied in response to night, day, and external environments. Each of the three gamma voltage generators 36 may be provided. (At this time, the total number of resistors included in the gamma voltage supply 26 is set to 27).

The data integrated circuit 30 divides the reference gamma voltage supplied from the gamma voltage supply unit 26 into a plurality of levels to generate a data signal corresponding to data. To this end, the data integrated circuit 30 may include a shift register 40, a first latch array 42, a second latch array 44, and a digital analog converter. DAC section "46 and an output array 48 are provided.

The shift register unit 40 is composed of a plurality of shift registers to generate a sampling signal while shifting a start pulse supplied from the outside corresponding to the shift clock.

The first latch array 42 includes a first R latch portion 42a, a first G latch portion 42b, and a first B latch portion 42c. The first R latch section 42a temporarily stores the R data supplied from the outside in response to the sampling signal supplied from the shift register section 40. The first G latch section 42b temporarily stores G data supplied from the outside in response to the sampling signal supplied from the shift register section 40. The first B latch section 42c temporarily stores the B data supplied from the outside in response to the sampling signal.

The second latch array 44 receives data temporarily stored in the first latch array 42 and simultaneously supplies the stored data corresponding to the out enable signal supplied from the outside to the DAC unit 46. To this end, the second latch array 44 includes a second R latch portion 44a, a second G latch portion 44b, and a second B latch portion 44c. The second R latch unit 44a receives the data stored in the first R latch unit 42a and supplies the data to the DAC unit 46 in response to the out enable signal. The second G latch unit 44b receives the data stored in the first G latch unit 42b and supplies the data to the DAC unit 46 in response to the out enable signal. The second B latch unit 44c receives the data stored in the first B latch unit 42c and supplies the data to the DAC unit 46 in response to the out enable signal.

The DAC unit 46 converts the data supplied from the second latch array 44 into an analog data signal corresponding to the number of bits and supplies it to the output array 48. To this end, the DAC unit 46 includes an R DCA unit 46a, a G DAC unit 46b, and a B DAC unit 46c.

The R DAC unit 46a receives the low grayscale R gamma voltage VH_R and the high grayscale R gamma voltage VL_R from the gamma voltage supply unit 26. Here, the R DAC unit 46a generates a plurality of gamma voltages using the low gray level R gamma voltage VH_R and the high gray level R gamma voltage VL_R. Generates a gamma voltage), and the R DAC unit 46a selects one of the gamma voltages corresponding to the bits of data supplied from the second R latch unit 44a to generate a data signal, and generates the data signal. Is supplied to the output array 48.

The G DAC unit 46b receives the low gray level G gamma voltage VH_G and the high gray level G gamma voltage VL_G from the gamma voltage supply unit 26. Here, the G DAC unit 46b generates a plurality of gamma voltages by using the low gray G gamma voltage VH_G and the high gray G gamma voltage VL_G. Generates a gamma voltage), and the G DAC unit 46b selects one of the gamma voltages corresponding to the bits of the data supplied from the second G latch unit 44b to generate a data signal, and generates the data signal. Is supplied to the output array 48.

The B DAC unit 46c receives the low gray level B gamma voltage VH_B and the high gray level B gamma voltage VL_B from the gamma voltage supply unit 26. Here, the B DAC unit 46c generates a plurality of gamma voltages using the low gray level B gamma voltage VH_B and the high gray level B gamma voltage VL_B. Generates a gamma voltage), and the B DAC unit 46c selects one of the gamma voltages corresponding to the bits of the data supplied from the second B latch unit 44c to generate a data signal, and generates the data signal. Is supplied to the output array 48.

The output array 48 supplies the data signal supplied from the DAC unit 46 to the respective data electrode lines DL. To this end, the output array 48 includes a first output unit 48a, a second output unit 48b, and a third output unit 48c. The first output unit 48a supplies the data signal supplied from the R DAC unit 46a to the data electrode lines DL formed in the R cells. The second output unit 48b supplies the data supplied from the G DAC unit 46b to the data electrode lines DL formed in the G cells. The third output unit 48c supplies data supplied from the B DAC unit 48c to the data electrode lines DL formed in the B cells.

That is, the above-described gamma voltage supply unit 26 of the EL display device supplies different reference gamma voltages corresponding to the R cells, the G cells, and the B cells to the data driver 24, and the data drivers 24 mutually. By using different reference gamma voltages, data signals to be supplied to the R cells, the G cells, and the B cells are generated to display a desired image.

However, in such a conventional EL display device, variations in luminance between the EL display panels 20 occur due to variations in manufacturing processes. In other words, each of the plurality of EL display panels 20 displays images of different luminance corresponding to the same data. In order to prevent this, conventionally, the luminance value between the EL display panels 20 is compensated by adjusting the resistance values of the resistors included in the gamma voltage supply unit 26. However, when the luminance deviation is compensated using the resistance values of the resistors as described above, a lot of processing time is additionally consumed, and accurate luminance deviation compensation is impossible.

In addition, the conventional data integrated circuit 30 is mounted on a chip on film (COF) 50 as shown in FIG. 5, and the resistors of the gamma voltage supply unit 26 are mounted on a flexible printed circuit (FPC) 52. That is, since a plurality of resistors of the gamma voltage supply unit 26 are installed, the resistors of the gamma voltage supply unit 26 are not mounted in the COF 50 but are installed in the FPC 52. However, when the FPC 52 is installed for the resistors of the gamma voltage supply unit 26, additional manufacturing costs are wasted. In addition, a lot of processing time is additionally consumed for the alignment of the FPC 52 and the COF 50.

Accordingly, an object of the present invention is to provide an electro-luminescence display device capable of shortening the process time and reducing the manufacturing cost.

In order to achieve the above object, the electro-luminescence display device of the present invention includes a gamma generator for outputting a reference gamma voltage corresponding to control data supplied from the outside; At least one data integrated circuit for receiving data from the outside and generating a data signal corresponding to the number of data bits by using the reference gamma voltage is provided.

The gamma generator includes a red gamma unit for generating a red reference gamma voltage to generate a data signal to be supplied to a red cell, and a green gamma unit for generating a green reference gamma voltage to generate a data signal to be supplied to a green cell. And a blue gamma unit for generating a blue reference gamma voltage so that a data signal to be supplied to the blue cell can be generated.

The red gamma part, the green gamma part, and the blue gamma part respectively divide the first resistor part and the second resistor part for dividing the voltage of the supply voltage source, and the divided voltage supplied from the first resistor part to a plurality of voltage levels. The first analog digital converter for dividing the divided voltage supplied from the second resistor unit into a plurality of voltage levels, and the first analog digital converter for outputting any one voltage. And a register for supplying the second control data to supply the first control data and to output one of the voltages from the second analog digital converter.

Each of the first resistor portion and the second resistor portion includes three resistors so as to divide the voltage of the supply voltage source into two voltage values.

Bit values of the first and second control data are set such that a plurality of electro-luminescence displays can display uniform luminance.

The gamma generator and the data integrated circuits are mounted on a chip on film (COF).

The red reference gamma voltage, the green reference gamma voltage, and the blue reference gamma voltage are set to match white balance in the red cells, the green cells, and the blue cells.

The gamma generator is integrated in the data integrated circuit.

Other objects and features of the present invention in addition to the above objects will become apparent from the description of the embodiments with reference to the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described with reference to FIGS. 6 to 9.

Fig. 6 is a diagram showing an EL display device according to the first embodiment of the present invention. Here, in the first embodiment of the present invention, it is assumed that at least two or more data integrated circuits 66 are mounted in the data driver 64.

Referring to FIG. 6, the EL display device according to the first embodiment of the present invention includes an EL display panel including EL cells 70 arranged at intersections of the scan electrode line SL and the data electrode line DL. 60, a scan driver 62 for driving the scan electrode lines SL, and a data driver 64 for driving the data electrode lines DL.

Each of the EL cells 70 is selected when a scan pulse is applied to the scan electrode line SL to generate light corresponding to the data signal supplied to the data electrode line DL. That is, a predetermined image is displayed on the EL display panel 60 because a predetermined light corresponding to the data signal is generated in each of the EL cells 70.

The scan driver 62 sequentially supplies scan pulses to the plurality of scan electrode lines SL.

The data driver 64 includes a plurality of data integrated circuits 66 and a gamma generator 100.

The data integrated circuits 66 are configured as shown in FIG. 4 to generate a data signal by dividing the reference gamma voltage supplied from the gamma generator 100 to a plurality of voltage levels, and converting the generated data signal into data electrode lines ( DL). In other words, the data integrated circuits 66 generate a data signal by selecting a voltage level corresponding to the number of bits of data, and supply the generated data signal to be synchronized with the scan pulse.

The gamma generator 100 is included in the data driver 64 to supply reference gamma voltages to the data integrated circuits 66. To this end, the gamma generator 100 includes an R gamma generator 68R, a G gamma generator 68G, and a B gamma generator 68B.

The R gamma generator 68R generates a low gray level R gamma voltage VH_R and a high gray level R gamma voltage VL_R and supplies the same to the data integrated circuits 66. The G gamma generator 68G generates a low gray level G gamma voltage VH_G and a high gray level G gamma voltage VL_G and supplies the same to the data integrated circuits 66. The B gamma generator 68B generates and supplies the low gray level B gamma voltage VH_B and the high gray level B gamma voltage VL_B to the data integrated circuits 66.

To this end, the R gamma generator 68R includes resistors 80 and 82, DACs 84 and 86, and a resistor 88 as shown in FIG. 7A.

The resistor units 80 and 82 include a first resistor unit 80 and a second resistor unit 82. The first resistor unit 80 includes divided voltage resistors r_R1_H, r_R2_H, and r_R3_H provided between the supply voltage source VDD and the base voltage source GND. Here, the first and second voltages divided by the divided resistors r_R1_H, r_R2_H, and r_R3_H are supplied to the DAC unit 84. The second resistor unit 82 includes voltage dividers r_R1_L, r_R2_L, and r_R3_L provided between the supply voltage source VDD and the base voltage source GND. Here, the third and fourth voltages divided by the divided resistors r_R1_H, r_R2_H, and r_R3_H are supplied to the DAC unit 86.

The DAC units 84 and 86 include a first DAC unit 84 and a second DAC unit 86. The first DAC unit 84 divides the first voltage and the second voltage into a plurality of voltage levels. (For example, if the i (i is a natural number) bit is input from the register 88, the first and second voltages are divided. 2 is ⁱ dogs divided in voltage level), and, the 1DAC section 84 is R gamma of low gray scale to any one of the voltage of the corresponding partial pressure of the plurality of voltage levels to the number of bits of the control data supplied from the register 88, The voltage VH_R is supplied to the data integrated circuits 66.

The 2DAC part 86 is the third voltage and the partial pressure of the fourth voltage to the plurality of voltage levels (for example, if the i-bit input from the register 88, the third and the fourth voltage is 2 ^i-circuit voltage level The second DAC unit 86 sets the voltage of any one of a plurality of voltage levels divided in correspondence to the number of bits of the control data supplied from the register 88 as a high gray level R gamma voltage VL_R. Supply to data integrated circuits 66.

I-bit control data is input to the register 88 to control the output voltage values of the first and second DAC units 84 and 86, respectively. In other words, the first control data input to the register 88 is supplied to the first DAC unit 84 to control the first DAC unit 84. The second control data input to the register 88 is supplied to the second DAC unit 86 to control the second DAC unit 86. Here, the bit values of the first and second control data input to the register 88 are determined by the user. For example, the register 88 may store first and second control data values capable of compensating for the luminance deviation generated between the EL display panels 60.

In detail, when the luminance deviation between the EL display panels 60 is generated, the user can compensate for the luminance deviation between the EL display panels 60 by adjusting the first and second data values input to the register 88. have. In addition, a mode control unit (not shown) is provided in front of the register 88, and the register 88 receives the first and second control data from the mode control unit to control output values of the first and second DAC units 84 and 86. By doing so, it is possible to control to display an image having an appropriate luminance corresponding to the external environment (for example, day, night, rain, snow ...).

Meanwhile, in the present invention, the G gamma generator 68G and the B gamma generator 68B are configured in the same manner as the R gamma generator 68R as illustrated in FIGS. 7B and 7C. However, the values stored in the registers 88 included in the G gamma generator 68G and the B gamma generator 68B are set to balance the white balance of the R cells, the G cells, and the B cells. Other operations are the same as the R gamma generator 68R of FIG. 7A described above, and thus a detailed description thereof will be omitted.

Meanwhile, in the present invention, the gamma generator 100 includes a smaller number of resistors than the conventional gamma voltage supply unit 26 shown in FIG. 3. Therefore, the gamma generator 100 of the present invention may be mounted in the COF 102 together with the data integrated circuit 66 as shown in FIG. 8. As such, when the gamma generator 100 is mounted on the COF 102, the manufacturing cost may be reduced.

9 is a diagram showing an EL display device according to a second embodiment of the present invention. Here, in the second embodiment of the present invention, it is assumed that one data integrated circuit 200 is mounted in the data driver 64. In the description of FIG. 9, the same components as those of FIG. 6 are assigned the same reference numerals, and detailed description thereof will be omitted.

Referring to FIG. 9, an EL display device according to a second embodiment of the present invention includes an EL display panel including EL cells 70 arranged at intersections of a scan electrode line SL and a data electrode line DL. 60, a scan driver 62 for driving the scan electrode lines SL, and a data driver 64 for driving the data electrode lines DL.

Each of the EL cells 70 is selected when a scan pulse is applied to the scan electrode line SL to generate light corresponding to the data signal supplied to the data electrode line DL. That is, a predetermined image is displayed on the EL display panel 60 because a predetermined light corresponding to the data signal is generated in each of the EL cells 70.

The scan driver 62 sequentially supplies scan pulses to the plurality of scan electrode lines SL.

The data driver 64 includes one data integrated circuit 200. The gamma generator 100 is embedded in the data integrated circuit 200. The other configuration is configured as shown in FIG.

The gamma generator 100 includes an R gamma generator 68R, a G gamma generator 68G, and a B gamma generator 68B. The R gamma generator 68R generates a low grayscale R gamma voltage VH_R and a high grayscale R gamma voltage VL_R and supplies the same to the R DAC unit 200a. The G gamma generator 68G generates a low grayscale G gamma voltage VH_G and a high grayscale G gamma voltage VL_G and supplies it to the G DAC unit 200b. The B gamma generator 68B generates a low gray level B gamma voltage VH_B and a high gray level B gamma voltage VL_B and supplies it to the B DAC unit 200c.

Here, the configurations of the R gamma generator 68R, the G gamma generator 68G, and the B gamma generator 68B are set in the same manner as in FIGS. 7A to 7C. Therefore, detailed operation of each gamma generator 68R, 68G, 68B will be omitted.

Comparing the second embodiment of the present invention with the first embodiment, the gamma generator 100 is integrated in the data integrated circuit 200 in the second embodiment of the present invention. As such, when the gamma generator 100 is integrated into the data integrated circuit 200, the mounting time may be shortened.

As described above, the electro-luminescence display device according to the present invention can adjust the reference gamma voltage using the control data stored in the register, thereby compensating the luminance deviation between the display panels in a short time. Therefore, the process time can be shortened. In addition, since the reference gamma voltage is selected from one of a plurality of voltage levels, the luminance deviation can be accurately compensated for. In addition, in the present invention, since the gamma voltage generation unit is mounted in the COF, the FPC is not additionally installed, thereby reducing the manufacturing cost. In addition, since the alignment time of COF and FPC is shortened, an additional effect of shortening the process time may be obtained.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

Claims (8)

A gamma generator configured to generate a red reference gamma voltage, a green reference gamma voltage, and a blue reference gamma voltage corresponding to control data supplied from the outside; And at least one data integrated circuit configured to generate a data signal corresponding to the number of bits of data supplied from the outside using the red reference gamma voltage, the green reference gamma voltage, and the blue reference gamma voltage. Electro-luminescence display. The method of claim 1, The gamma generator A red gamma unit for generating the red reference gamma voltage to generate the data signal to be supplied to the red cell; A green gamma unit for generating the green reference gamma voltage to generate the data signal to be supplied to the green cell; And a blue gamma unit for generating the blue reference gamma voltage so that the data signal to be supplied to the blue cell can be generated. The method of claim 2, Each of the red gamma part, the green gamma part, and the blue gamma part A first resistor portion and a second resistor portion for dividing the voltage of the supply voltage source, A first analog digital conversion unit for dividing the divided voltage supplied from the first resistor unit into a plurality of voltage levels; A second analog digital conversion unit for dividing the divided voltage supplied from the second resistor unit into a plurality of voltage levels; A register for supplying the first control data so that any one voltage can be output from the first analog digital converter, and to supply the second control data so that any one voltage can be output from the second analog digital converter. An electro-luminescence display device comprising: The method of claim 3, wherein And each of the first and second resistor parts includes three resistors to divide the voltage of the supply voltage source into two voltage values. The method of claim 4, wherein And the bit values of the first and second control data are set such that a plurality of the electro-luminescence displays can display a uniform brightness. The method of claim 1, And the gamma generator and the data integrated circuits are mounted on a chip on film (COF). The method of claim 2, And the red reference gamma voltage, the green reference gamma voltage, and the blue reference gamma voltage are set to match white balance in the red cells, the green cells, and the blue cells. The method of claim 1, And the gamma generator is integrated in the data integrated circuit.

Images