KR100602063B1 - Apparatus of generating gamma voltage - Google Patents

Abstract

The present invention relates to a gamma voltage generating device that can simplify the structure by reducing the number of parts.

The gamma voltage generator operating in various modes to change the luminance value in response to the external environment according to the present invention generates a plurality of red gamma voltages so that the luminance value can be changed corresponding to each mode. And a red gamma voltage generation unit including at least one variable resistor for adjusting the plurality of red gamma voltages, and generating a plurality of green gamma voltages so that the luminance values can be changed corresponding to the respective modes. And a green gamma voltage generator including at least one variable resistor for controlling the plurality of green gamma voltages, and generating a plurality of blue gamma voltages so that the luminance values can be changed corresponding to the respective modes. In addition, a blue gamma including at least one variable resistor for adjusting the plurality of green gamma voltages. And a pressure generating unit.

Description

Gamma Voltage Generator {APPARATUS OF GENERATING GAMMA VOLTAGE}             

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

2 is a view showing a driving device of a conventional organic electroluminescent display panel.

3 is a circuit diagram illustrating in detail a gamma voltage generator shown in FIG. 2 when a first mode is selected.

FIG. 4 is a circuit diagram illustrating in detail a gamma voltage generator shown in FIG. 2 when a second mode is selected.

FIG. 5 is a circuit diagram illustrating in detail a gamma voltage generator shown in FIG. 2 when a third mode is selected.

6 is a circuit diagram illustrating a gamma voltage generator according to an 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 electro-luminescence panel

22: scan driver 24: data driver

26 gamma voltage generator 28 EL cell

30: cell driver 32, 42: red gamma voltage generator

33,44: green gamma voltage generator 36,46: blue gamma voltage generator

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for generating a gamma voltage for use in a display device, and more particularly, to a gamma voltage generation device for simplifying a structure by reducing the number of parts.

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.

2 is a diagram showing a general EL display device.

The EL display device illustrated in FIG. 2 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. The scan driver 22 for driving the?, The data driver 24 for driving the data electrode lines DL, and the gamma voltage generator 26 for supplying a plurality of gamma voltages to the data driver 24 It is provided.

Each of the EL cells 28 is selected when a scan pulse is applied to the scan electrode line SL, which is a cathode, to generate light corresponding to a pixel signal, that is, a current signal, supplied to the data electrode line DL, which is an anode. 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. In contrast, the reverse direction voltage is applied to the EL cells 28 included in the unselected scan lines so as not to emit light. In other words, the EL cells 28 that emit light are charged with forward charges, while the EL cells 28 that do not emit light are charged with reverse charges.

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

The data driver 24 converts the digital data signal input from the outside into an analog data signal by using the gamma voltage from the gamma voltage generator 26. The data driver 24 supplies the analog data signal to the data lines DL every time a scan pulse is supplied.

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 the same level of data signal 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 gamma voltages to the data driver 24 generates gamma voltages for each of R, G, and B.

FIG. 3 is a circuit diagram illustrating in detail the gamma voltage generator illustrated in FIG. 2.

Referring to FIG. 3, the conventional gamma voltage generator includes an R gamma voltage generator 32, a G gamma voltage generator 34, and a B gamma voltage generator to supply gamma voltages to R, G, and B cells, respectively. 36).

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, voltages from the common terminals n1 and n2 of the divided resistors r_R1, r_R2 and r_R3 are input to the data driver 24 as gamma voltages. At this time, the low grayscale R gamma voltage VH_R is generated by Equation 1 below, and the high grayscale R gamma voltage VL_R is generated by Equation 2 below.

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 from the common terminals n3 and n4 of the divided resistors r_G1, r_G2 and r_G3 are input to the data driver 24 as gamma voltages. At this time, the low grayscale G gamma voltage VH_G is generated by Equation 3 below, and the high grayscale G gamma voltage VL_G is generated by Equation 4 below.

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 from the common terminals n5 and n6 of the divided resistors r_B1, r_B2 and r_B3 are input to the data driver 24 as gamma voltages. At this time, the low gray level B gamma voltage VH_B is generated by Equation 5 below, and the high gray level B gamma voltage VL_B is generated by Equation 6 below.

On the other hand, such a conventional EL display device further includes a gamma voltage generation unit for each mode as shown in FIGS. 4 and 5 so that the luminance is changed corresponding to various environments. Here, the resistances included in the gamma voltage generator for each mode are set so that luminance corresponding to an environment (light) such as night, day, outside, and inside may be generated.

For example, the R gamma voltage generator 32 of the second mode gamma voltage generator illustrated in FIG. 4 may include the divided resistors r_R4, r_R5, which are connected in series between the supply voltage source VDD and the ground voltage source GND. r_R6). Here, the resistance values of the divided resistors r_R4, r_R5, and r_R6 are set differently from the resistance values of the divided resistors r_R1, r_R2, and r_R3 included in the R gamma voltage generator 32 of FIG. 3. Therefore, the gamma voltage value generated from the second mode gamma voltage generator is set to be different from the gamma voltage value generated by the R gamma voltage generator 32 shown in FIG. 3, and the gamma voltage value corresponds to the environment. By supplying to the EL display device, an optimum luminance corresponding to the external environment can be generated in the EL table market value. Here, the resistance values of the divided resistors r_R7, r_R8, and r_R9 are measured by the divided resistors r_R1, r_R2, r_R3, r_R4, r_R5, and r_R6 included in the R gamma voltage generator 32 of FIGS. 3 and 4. It is set differently from the resistance value.

However, the gamma voltage generation unit corresponding to each mode is a high gray scale R gamma voltage VL_R and a low gray scale R gamma voltage VH_R supplied to the R cell, and a high gray scale G gamma voltage supplied to the G cell. (VL_G) and the low grayscale G gamma voltage (VH_G) and the high grayscale B gamma voltage (VL_B) and the low grayscale B gamma voltage (VH_B) should be generated. That is, the high gray level gamma voltages VL_R, VL_G, and VL_B and the low gray level gamma voltages VH_R, VH_G, and VH_B supplied to each of the R, G, and B cells must be generated. To this end, the R, G, and B gamma voltage generators 32, 34, and 36 of the gamma voltage generator are each of the high gray gamma voltages VL_R, VL_G, VL_B and low gray gamma between three resistors connected in series. Since voltages VH_R, VH_G, and VH_B are generated, a total of nine resistors for each mode are installed. Therefore, when three modes are used, a total of 27 resistors must be installed in the conventional gamma voltage generator. Accordingly, there is a problem that the structure is complicated by the large number of parts that differ on the module.

Accordingly, it is an object of the present invention to provide a gamma voltage generating device which can simplify the structure by reducing the number of parts.

In order to achieve the above object, a gamma voltage generating device operating in various modes so that the luminance value can be changed in response to an external environment according to an embodiment of the present invention can be changed in response to the respective modes. A red gamma voltage generation unit including at least one variable resistor for generating a plurality of red gamma voltages and adjusting the plurality of red gamma voltages, and the luminance values corresponding to the respective modes may be changed. And a green gamma voltage generation unit including at least one variable resistor for generating a plurality of green gamma voltages and controlling the plurality of green gamma voltages, and the luminance values corresponding to the respective modes may be changed. At least one for generating a plurality of blue gamma voltages and adjusting the plurality of green gamma voltages. A blue gamma voltage generator including the above variable resistor is provided.

In the gamma voltage generator, each of the red, green, and blue gamma voltage generators includes a supply voltage source, a first resistor and a variable resistor connected to the supply voltage source, and i (in parallel) connected between the variable resistor and the base voltage source. i is a natural number).

The gamma voltage generator includes a variable resistor connected to the first common terminal and the base voltage source in parallel with a gamma voltage generated from a first common terminal between the first resistor and the variable resistor, and connected in parallel with the first common terminal and the base voltage source. A gamma voltage corresponding to the second gray level is generated from the common terminal of the i parallel resistors.

The gamma voltage generator is characterized in that switches are installed between the i parallel resistors and the base voltage source.

The gamma voltage generator is a voltage of a gamma voltage corresponding to the first and second gray levels when the switches are turned on and off in correspondence to the respective modes, and the switches are turned on and off. It is characterized in that the value is changed.

In the gamma voltage generator, resistance values of the first resistor, the variable resistor, and the i parallel resistors may be differently set in each of the red, green, and blue gamma voltage generators.

In the gamma voltage generator, resistance values of the resistors included in each of the red, green, and blue gamma voltage generators may be set to match the white balance of the red cells, the green cells, and the blue cells.

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 FIG. 6.

6 is a circuit diagram illustrating a gamma voltage generator according to an exemplary embodiment of the present invention.

Referring to FIG. 6, the gamma voltage generator of the present invention generates an R gamma voltage generator 42, a G gamma voltage generator 44, and a B gamma voltage to supply gamma voltages for R, G, and B cells, respectively. The unit 46 is provided. Here, each of the R, G, and B gamma voltage generators 42, 44, and 46 generates gamma voltages of various modes so as to correspond to an external environment.

The R gamma voltage generator 42 generates a low gray R gamma voltage VH_R and a high gray R gamma voltage VL_R to supply a low gray (Black) and high gray (White) to the R cell. To this end, the R gamma voltage generator 42 includes a first voltage divider R1 and a first variable resistor VR1 connected directly to the supply voltage source VDD, a first variable resistor VR1 and a ground voltage source GND. The second and third voltage divider resistors R2 and R3 connected in parallel, the first switch S1 and the third voltage divider resistor connected between the second voltage divider resistor R2 and the ground voltage source GND. And a second switch S2 connected between R3) and the ground voltage source GND. Here, by using the first variable resistor VR1, the gamma voltage generator can effectively cope with various panel conditions. In other words, by using the first variable resistor VR1, it is possible to flexibly cope with a change in the resolution of the panel or a change in the material.

The G gamma voltage generator 44 generates a low gray G gamma voltage (VH_G) and a high gray G gamma voltage (VL_G) to supply a low gray (Black) and high gray (White) to the G cell. To this end, the G gamma voltage generator 44 includes an eleventh voltage divider R11 and a second variable resistor VR2 connected in series with a supply voltage source VDD, a second variable resistor VR2 and a ground voltage source GND. ), The 12th and 13th voltage divider resistors R12 and R13 connected in parallel, the first switch S1 connected between the 12th voltage divider resistor R12 and the ground voltage source GND, and the 13th voltage divider resistor ( And a second switch S2 connected between R13) and the ground voltage source GND. Here, by using the second variable resistor VR2, the gamma voltage generator can effectively cope with various panel conditions. In other words, by using the second variable resistor VR2, it is possible to flexibly cope with the change in the resolution of the panel or the change of the material.

The B gamma voltage generator 46 generates a low gray B gamma voltage VH_B and a high gray B gamma voltage VL_B to supply a low gray level to the B cell. To this end, the B gamma voltage generator 46 may include a twenty-first voltage divider R21 and a third variable resistor VR3, a third variable resistor VR3, and a base voltage source GND connected in series with a supply voltage source VDD. 22 and 23 divided voltage resistors R22 and R23 connected in parallel, a first switch S1 connected between a 22nd divided voltage resistor R22 and a ground voltage source GND, and a 23rd divided voltage resistor ( And a second switch S2 connected between the R23 and the ground voltage source GND. Here, by using the third variable resistor VR3, the gamma voltage generator can effectively respond to various panel conditions. In other words, by using the third variable resistor VR3, it is possible to flexibly cope with the change in the resolution of the panel or the change of the material.

On the other hand, the first mode is automatically selected when the first and second switches S1 and S2 are turned off. Accordingly, when the first mode is selected, the low gradation R gamma voltage VH_R and the high gradation R gamma voltage VL_R are connected to the first voltage divider R1 and the first voltage connected in series between the supply voltage source VDD and the base voltage source GND. The voltage is divided by one variable resistor VR1 to generate the voltage. When the first mode is selected, the low gradation G gamma voltage VH_G and the high gradation G gamma voltage VL_G are the eleventh voltage divider R11 and the eleventh voltage divider connected in series between the supply voltage source VDD and the base voltage source GND. The voltage is divided by the variable resistor VR2 to generate the voltage. In addition, when the first mode is selected, the low gray level B gamma voltage VH_B and the high gray level B gamma voltage VL_B are connected to the twenty-first voltage divider resistor R21 and the second voltage connected in series between the supply voltage source VDD and the base voltage source GND. The voltage is divided by the variable resistor VR3 to generate the voltage. Here, the high grayscale R, G, and B gamma voltages VL_R, VL_G, and VL_B generated by the R, G, and B gamma voltage generators 42, 44, and 46 are high gray, that is, white. In the case of the expression (the gray of the R, G, and B cells are combined to express white), the luminance difference occurs corresponding to the luminous efficiency of each of the R, G, and B cells. The supplied high gradation R gamma voltage (VL_R), high gradation G gamma voltage (VL_G) and high gradation B gamma voltage (VL_B) are set to be white balanced. In this case, in the case of expressing high gray, that is, white, R gamma voltage VL_R of high gray and G gamma voltage VL_G of high gray using the first to third variable resistors VR1 to VR3. High gradation B gamma voltage (VL_B) can be flexibly adjusted to effectively cope with various panel conditions.

When the second mode is selected, the first switch S1 is turned on. When the first switch S1 is turned on, the R gamma voltage generator 42 has a first variable resistor VR1 and a second voltage divider R2 between the first voltage divider R1 and the ground voltage source GND. (I.e., the resistance value is different from the first mode). Therefore, when the second mode is selected, the low gradation R gamma voltage VH_R and the high gradation R gamma voltage VL_R are supplied to the supply voltage source VDD. To the parallel resistance values of the first variable resistor VR1 and the second voltage divider resistor R2 connected in parallel between the first voltage divider resistor R1 and the first voltage divider resistor R1 and the ground voltage source GND. The voltage is divided and generated. When the first switch S1 is turned on, the G gamma voltage generator 44 may include the second variable resistor VR2 and the twelfth resistor R12 between the eleventh voltage divider R11 and the base voltage source GND. (I.e., the resistance value is different from the first mode). Therefore, when the second mode is selected, the low gray G gamma voltage VH_G and the high gray G gamma voltage VL_G are supplied to the supply voltage source VDD. To the parallel resistance values of the second variable resistor VR2 and the twelfth voltage divider R12 connected in parallel between the eleventh voltage divider R11 and the eleventh voltage divider R11 and the ground voltage source GND. The voltage is divided and generated. In addition, when the first switch S1 is turned on, the B gamma voltage generator 46 may include the third variable resistor VR3 and the 22nd voltage divider R22 between the eleventh resistor R11 and the base voltage source GND. (I.e., the resistance value is different from the first mode). Therefore, when the second mode is selected, the low gray B gamma voltage VH_B and the high gray B gamma voltage VL_B are supplied to the supply voltage source VDD. To the voltage divider resistance values of the third variable resistor VR3 and the 22nd voltage divider resistor R22 connected in parallel between the 21st voltage divider resistor R21 and the 21st voltage divider resistor R21 and the ground voltage source GND. The voltage is divided and generated. Here, the high grayscale R, G, and B gamma voltages VL_R, VL_G, and VL_B generated by the R, G, and B gamma voltage generators 42, 44, and 46 represent a high gray, that is, white. In this case, the luminance difference occurs in response to the luminous efficiency of each of the R, G, and B cells. (VL_G) and high gradation B gamma voltages (VL_B) are set so that the white balance is correct. In this case, in the case of expressing high gray, that is, white, R gamma voltage VL_R of high gray and G gamma voltage VL_G of high gray using the first to third variable resistors VR1 to VR3. High gradation B gamma voltage (VL_B) can be flexibly adjusted to effectively cope with various panel conditions.

When the third mode is selected, the first and second switches S1 and S2 are turned on. When the first and second switches S1 and S2 are turned on, the R gamma voltage generator 42 includes a first variable resistor VR1 and a second between the first voltage divider R1 and the ground voltage source GND. And the parallel resistance values of the third divided resistors R2 and R3 (i.e., the resistance values are different from the first and second modes). Thus, when selecting the third mode, the low gradation R gamma voltage VH_R and the high The gray level R gamma voltage VL_R includes a first variable resistor VR1 connected in parallel between a first voltage divider R1 connected to a supply voltage source VDD, a first voltage divider R1, and a base voltage source GND, The voltage is divided by the parallel resistance values of the second and third voltage divider resistors R2 and R3 to generate the same. When the first and second switches S1 and S2 are turned on, the G gamma voltage generator 44 may include a second variable resistor VR2 between the eleventh voltage divider R11 and the base voltage source GND. The parallel resistance values of the twelfth and thirteenth voltage divider resistors R12 and R13 appear (i.e., the resistance values are different from the first and second modes). Thus, a low grayscale G gamma voltage VH_G when the third mode is selected And the high gray G gamma voltage VL_G includes a second variable resistor VR2 connected in parallel between an eleventh voltage divider R11 connected to a supply voltage source VDD, an eleventh voltage divider R11, and a base voltage source GND. ) And the voltage are divided by the parallel resistance values of the twelfth and thirteenth voltage divider resistors R12 and R13. In addition, when the first and second switches S1 and S2 are turned on, the B gamma voltage generator 44 may include a third variable resistor VR3 between the twenty-first voltage divider R21 and the base voltage source GND. The parallel resistance values of the 22nd and 23rd voltage divider resistors R22 and R23 appear (i.e., the resistance values are different from the first and second modes). Therefore, the low gray level B gamma voltage VH_B when the third mode is selected. And the high gray level B gamma voltage VL_B includes a third variable resistor VR3 connected in parallel between the twenty-first voltage divider voltage R21 connected to the supply voltage source VDD, the twenty-first voltage divider resistor R21, and the base voltage source GND. ) And the voltage are divided by the parallel resistance values of the 22nd and 23rd voltage divider resistors R22 and R23. Here, the high grayscale R, G, and B gamma voltages VL_R, VL_G, and VL_B generated by the R, G, and B gamma voltage generators 42, 44, and 46 represent a high gray, that is, white. In this case, the luminance difference occurs in response to the luminous efficiency of each of the R, G, and B cells. (VL_G) and high gradation B gamma voltages (VL_B) are set so that the white balance is correct. In this case, in the case of expressing high gray, that is, white, R gamma voltage VL_R of high gray and G gamma voltage VL_G of high gray using the first to third variable resistors VR1 to VR3. High gradation B gamma voltage (VL_B) can be flexibly adjusted to effectively cope with various panel conditions.

On the other hand, the low gradation R gamma voltage (VH_R), the low gradation G gamma voltage (VH_G), and the low gradation B gamma voltages (VH_B) generated by the R, G, and B gamma voltage generators 42, 44, and 46 are low. In the case of expressing gray, that is, black (the gray of R, G, and B cells are combined to express black), a low grayscale R gamma supplied to the R, G, and B cells for each of the first to third modes Even if the voltage difference between the voltage VH_R, the low gray G gamma voltage VH_G, and the low gray B gamma voltages VH_B is difficult to recognize by the eye, it does not have a great influence.

The gamma voltage generator according to the present invention allows the R, G, and B gamma voltage generators 42, 44, and 46 to select the first to third modes, thereby generating a plurality of gamma voltages corresponding to the selected mode. Create The gamma voltages thus generated are supplied to the data driver shown in FIG. 1. The data driver generates an analog data signal using a gamma voltage corresponding to the input digital data signal among a plurality of gamma voltages, and supplies the generated analog data signal to the data line DL to be synchronized with the scan signal. The predetermined image is displayed.

As described above, the gamma voltage generating apparatus according to the present invention can reduce the number of parts in each of the red, green, and blue gamma voltage generating units, and can express gray scales, thereby simplifying the structure of the EL module. In addition, by using the variable resistor, the gamma voltage generator can effectively cope with various panel conditions.

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 (7)

In the gamma voltage generator that operates in various modes to change the luminance value in response to the external environment, A red gamma voltage generation unit including at least one variable resistor for generating a plurality of red gamma voltages to control the plurality of red gamma voltages so as to change the luminance value corresponding to each mode; A green gamma voltage generation unit including at least one variable resistor for generating a plurality of green gamma voltages to control the plurality of green gamma voltages so as to change the luminance value corresponding to each mode; A blue gamma voltage generation unit including a plurality of blue gamma voltages to generate the plurality of blue gamma voltages corresponding to the respective modes, and at least one variable resistor for controlling the plurality of green gamma voltages; Gamma voltage generator, characterized in that. The method of claim 1, Each of the red, green, and blue gamma voltage generators Supply voltage source, A first resistor and a variable resistor connected to said supply voltage source, And (i is a natural number) parallel resistances connected in parallel between the variable resistor and the base voltage source. The method of claim 2, A gamma voltage corresponding to a first grayscale is generated from a first common terminal between the first resistor and the variable resistor, And a gamma voltage corresponding to a second gray scale is generated from the common terminal of the variable resistor and the i parallel resistors connected in parallel between the first common terminal and the base voltage source. The method of claim 3, wherein And a switch is installed between the i parallel resistors and the base voltage source. The method of claim 4, wherein The switches are turned on and off in response to the respective modes, and when the switches are turned on and off, a voltage value of a gamma voltage corresponding to the first and second gray levels is changed. Gamma voltage generator. The method of claim 2, The gamma voltage generator of claim 1, wherein the resistance values of the first resistor, the variable resistor, and the i parallel resistors are set differently in the red, green, and blue gamma voltage generators. The method of claim 6, The gamma voltage generator of claim 1, wherein the resistance values of the resistors included in each of the red, green, and blue gamma voltage generators are set to match the white balance of the red, green, and blue cells.

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