JP2002296566A - Centrosymmetric gamma voltage calibration circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a centrosymmetric gamma voltage calibration circuit. SOLUTION: This circuit is applied to the display circuit of a liquid crystal display, and adjusts a gamma calibration voltage effectively and satisfactorily by the installation of one resistance voltage dividing circuit and one drive circuit. A gamma calibration voltage value is controlled by an input voltage from the outside, and the number of amplifiers necessary in the circuit and necessary calibration voltages inputted from the outside is reduced. A combination of a plurality of resistances, variable resistances and amplifiers is used together in the resistance voltage dividing circuit and the drive circuit, and the number of calibration voltages required to be inputted from the outside and the necessary number of amplifiers to be used are reduced.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a kind of centrally symmetric gamma voltage calibration circuit, particularly applied to a display circuit of a liquid crystal display. Reduce the number of calibration voltages required for input and the number of amplifiers required for use,
The present invention relates to a centrally symmetric gamma voltage calibration circuit.

[0002]

2. Description of the Related Art A gamma voltage calibration circuit is generally applied to an active matrix liquid crystal display, and its main function is to convert a digital code signal and to apply an appropriate image data to an input image corresponding to a characteristic curve of the liquid crystal display. Adjust the curve and pass through the conversion of this characteristic curve,
It consists in adjusting the brightness, gray scale, contrast and color representation of the display.

[0003] Please refer to FIGS. 1A illustrates the relationship between the image data code (Code) and the display characteristic (T) of the display, where T may be transmittance, luminance, gray scale, contrast, and color expression. FIG. 1B shows the display characteristics of a general liquid crystal display, and shows the voltage (Volta) of the liquid crystal display.
ge) shows the relationship between display characteristics (T). FIG. 1C is an ideal display image characteristic curve to be achieved, which corresponds to the characteristic curve of FIG. 1A. However, FIG.
In order to obtain the characteristic curve, it is necessary to compensate external data with an adjustment mechanism, input the data to the liquid crystal display, and then modify the characteristic according to the characteristics of the display itself. This adjustment mechanism is a gamma voltage calibration circuit. D in FIG. 1 is a conversion curve of a general gamma voltage calibration circuit, and shows the relationship between data code and voltage.

In a general twisted nematic mode liquid crystal display (TN-mode LCD), the characteristic curve of the transmittance versus voltage of the liquid crystal material itself becomes a single non-linear curve, which allows the liquid crystal material to be used in a gamma voltage circuit. Therefore, if the number of reference voltage points that can be provided increases, the error of the gamma voltage calibration circuit characteristic curve becomes relatively smaller, and under the demand for high image quality of the display, it is possible to provide 256 gray scales. Taking two 8-bit data drivers as an example, the 256 gray scales need to be adjusted by providing 256 externally adjustable reference voltages for the best adjustment, and one Need to be adjusted step by step. Since it is necessary that the driving voltage of the liquid crystal material has an AC characteristic, 256 reference voltage points for each of the positive and negative polarities are required, and therefore, adjustment by a total of 512 external input reference voltages is required. is there. In this situation, forming such a large number of reference voltage inputs on one driver IC is a rather impractical method, and in practice very few people adopt such a method. For this reason, in a general design, a small number of finite reference voltage input terminals are provided from the outside, and a fixed proportional resistance voltage dividing method is designed inside the driver IC to form a necessary reference voltage point. To obtain a reference voltage not provided from outside. However, the voltage divided by the resistor voltage divider circuit is limited by the reference voltage and the voltage dividing resistance value provided from the outside, and the curve of the liquid crystal display is also relatively limited, that is, the characteristic curve is approximate. Sometimes they had relatively large errors.

FIG. 2 shows a known gamma voltage calibration circuit of a fixed proportional resistance division. As shown in FIG. 2, in a general DC voltage driving method, the data driver 3 is usually
Requires a set of voltage center symmetric gamma calibration voltage inputs,
This center voltage is obtained from V _COM = (V _CC + V _GND ) / 2. The input voltage (V _CC; V _GND), after being divided is transmitted through one of the resistive divider 1, to obtain a plurality of voltage dividing point. The plurality of voltage dividing points are further connected to the drive circuit 2 and, after gain amplification of the voltage, are connected to the data driver 3 to obtain a necessary calibration voltage at the time of positive and negative polarity driving. As shown in FIG. 2, a multi-point output is obtained using the relatively simple skewing resistance partial pressure method of this structure. However, in this circuit, it is rather difficult to appropriately adjust the voltage level, and it is difficult to symmetrically adjust the voltage centers of the positive and negative polarities, so that in such a circuit structure, any one of Changing the resistance changed other output voltages.

FIG. 3 is a graph showing the lightning effect characteristics of a voltage drive of a general liquid crystal display. It shows the relationship between the drive voltage and the display characteristics of the display.
V _COM (common voltage) in the figure is the center voltage of the characteristic curve, and the value of the center voltage is determined by the voltage applied from the outside. The characteristic curve has a symmetrical distribution toward both sides of the center voltage, and is divided into a positive polarity area and a negative polarity area from the center voltage point toward both side areas. The positive polarity area and the negative polarity area are the origins of the necessary positive and negative polarity voltages in the LCD display.

[0007]

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned drawbacks of the prior art. SUMMARY OF THE INVENTION It is a main object of the present invention to provide a kind of gamma voltage calibration circuit having a tunable center symmetry so that the display characteristics of a liquid crystal display can be effectively and well expressed by implementing the present invention.

It is another object of the present invention to implement the modulatable center symmetric voltage of the present invention on a resistive voltage divider circuit, thereby obtaining an effective and good adjustment scheme for the gamma calibration voltage.

Still another object of the present invention is to implement the gamma voltage of the present invention on a resistive voltage dividing circuit so that the gamma calibration voltage can be controlled by an externally input voltage. Accordingly, it is an object of the present invention to provide a control system which is simpler, more convenient and elastic.

It is yet another object of the present invention to reduce the number of amplifiers required in a gamma voltage circuit by implementing the present invention, thereby reducing the number of elements required by the circuit.

It is a further object of the present invention to reduce the number of external input calibration voltages required in a gamma voltage circuit by implementing the present invention, thereby reducing the number of pins required for gamma calibration voltage input. .

[0012]

SUMMARY OF THE INVENTION The invention of claim 1 comprises a drive circuit, the drive circuit having a plurality of amplifiers or buffers, the drive circuit receiving a plurality of external reference voltages, and providing the same. Output to an external data driver, the data driver receiving the output of the gamma voltage calibration circuit and converting the output result to a slightly set of voltages, wherein the gamma voltage calibration circuit comprises one gamma voltage calibration circuit. A voltage dividing circuit, wherein the voltage dividing circuit is composed of several sets of voltage dividing sub-circuits, and each one of the voltage dividing sub-circuits is composed of some number of resistance elements, of which at least some of the resistance elements are included. One variable resistance element is included, and by adjusting the variable resistance element, one voltage is output at both ends of the variable resistance element, and the obtained output result is connected to the input terminal of the data driver. Characterized in that it is, it is set to gamma voltage calibration circuit centrosymmetric. According to the invention of claim 2, the voltage obtained at both ends of the variable resistor is adjusted by adjusting the variable resistor so that the voltage value at both ends becomes a center-symmetric voltage adjustment mode with respect to an intermediate value of the voltage values at both ends. A centrally symmetric gamma voltage calibrating circuit according to claim 1 is characterized in that: The invention according to claim 3 is characterized in that the voltage obtained at both ends of the variable resistance element is a positive or negative polarity voltage of one of a few sets required by the data driver. A centrally symmetric gamma voltage calibration circuit according to claim 1 is provided. According to a fourth aspect of the present invention, when the number of input terminals of the data driver is 2N, the number of output terminals of the driving circuit is N, and the number of output terminals of the voltage dividing circuit is also N. A centrally symmetric gamma voltage calibration circuit according to claim 1. Claim 5
According to the invention, in a centrally symmetric gamma voltage calibration circuit, a driving circuit is provided, which has a plurality of amplifiers or buffers, and the driving circuit receives a plurality of external reference voltages, and outputs a processed result. The drive circuit and the voltage divider circuit are composed of a few sets of voltage divider sub-circuits, each one voltage divider sub-circuit is composed of a small number of resistance elements,
At least one variable resistance element is included in some of the resistance elements, and the voltage division circuit outputs one voltage at both ends by adjusting the variable resistance element. The output of the drive circuit and the output of the voltage divider are input terminals of one external data driver,
A centrally symmetric gamma voltage calibration circuit characterized in that the data driver obtains the output result of the gamma voltage calibration circuit, converts the result, and outputs a slight set of voltages. According to a sixth aspect of the present invention, the voltage obtained at both ends of the variable resistor is adjusted by adjusting the variable resistor so that the voltage value at both ends becomes a center-symmetric voltage adjustment mode with respect to an intermediate value of the voltage values at both ends. A centrally symmetric gamma voltage calibration circuit according to claim 5 characterized in that: The invention according to claim 7 is characterized in that the voltage obtained at both ends of the variable resistance element is a positive or negative polarity voltage of one of a few sets required by the data driver. A centrally symmetric gamma voltage calibration circuit according to claim 5 is provided. The invention according to claim 8 is characterized in that when the number of input terminals of the data driver is 2N, the number of output terminals of the driving circuit is N and the number of output terminals of the voltage dividing circuit is also N. A centrally symmetric gamma voltage calibration circuit according to claim 5 is provided.

[0013]

DETAILED DESCRIPTION OF THE INVENTION The present invention overcomes the shortcomings of the prior art by implementing a gamma voltage calibration circuit with a tunable center symmetry. In the basic composition circuit, which is composed of a resistor, a variable resistor, and an amplifier, externally inputs a voltage, and divides the voltage jointly by the resistor and the variable resistor and adjusts the variable resistor. To obtain the positive and negative polarity calibration voltages respectively.

In one preferred embodiment of the present invention connected to a data driver, if the number of input calibration voltages required by the data driver is 2N, after the design of this preferred embodiment, The OP buffer in the drive circuit holds half of the connection with the data driver, and the other half of the voltage is provided by the output connection across the variable resistor in the tunable center-symmetric gamma voltage calibration circuit. , No further connection to the OP buffer is required.

The gamma calibration voltage required through the design of the present invention and externally input can be minimized, and the non-externally input calibration voltage is adjusted by a voltage dividing circuit and a variable resistor. can do.

[0016]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention provides a kind of centrally symmetric gamma voltage calibration circuit. According to the embodiment of the present invention, an effective and good expression is provided for the display characteristics of the liquid crystal display, and an effective and good adjustment method for the gamma calibration voltage is obtained. It is possible to reduce the number of necessary calibration reference voltages input from the outside by reducing the number of necessary amplifiers and reduce the number of necessary amplifiers, and to reduce the level of the calibration voltage by the voltage input from the outside by the combination design of the resistor divider circuit and the amplifier or buffer. adjust.

The gamma voltage calibration circuit of the present invention has a set of voltage signals, and the output is connected to a data driver, which further converts the voltage signal received by the gamma calibration voltage data driver. Further, there are a plurality of sets of voltage signals, and the number of the voltage signals affects display characteristics of the liquid crystal display.

FIG. 4 shows the basic circuit composition of the preferred embodiment of the present invention. As shown in FIG. 4, it is composed of two resistors, one variable resistor and two buffers, which in this embodiment are composed of an amplifier (OP),
When a voltage V _CC is input from the outside, the voltage is applied to the resistors Ra and R
b and the variable resistor VR. When the resistance values of the resistors Ra and Rb are the same, the variable resistor V
By the resistance value of R is adjusted, the variable across the output voltage of the resistor VR is obtained, after being connected further to a respective one of the amplifiers OP _1, to obtain a different voltage value of two, respectively. The voltage obtained at both ends of the variable resistor VR by adjusting the variable resistor VR is one data driver (not shown) in connection with a subsequent circuit.
To provide a set of positive and negative polarity drive voltages, eg, one positive polarity calibration voltage (V _th ⁺ ) and one negative polarity calibration voltage (V
_th ^-) to provide. A feature of the present invention is that the adjustment of the variable resistor causes the gamma voltage calibration circuit to form a mode of centrally symmetric voltage, thereby providing a favorable symmetrical positive and negative voltage curve at the central voltage of the gamma voltage calibration circuit. Generate a result.

Please refer to FIG. 3 and FIG. For example, when the input voltage is 12 V (V _CC + V _GND = 12 V), Ra and Rb are both 400Ω, and the range of VR is 0 to 1
When KΩ, that is, VR is adjusted to 400Ω, the obtained negative polarity voltage is 4V and the positive polarity voltage is 8V.
The intermediate value is the center voltage V _COM = (V _CC + V
A _{GN D)} / 2 = 6V.

Of course, when the present invention is actually implemented, preferable results can be obtained by appropriately adjusting and designing the input voltage value, the resistance value, and the variable resistance value in consideration of the structure of the entire display circuit. .

FIG. 5 is an electric circuit diagram of a preferred embodiment in which the present invention is connected to one data driver. As shown in FIG. 5, the resistive voltage dividing circuit 10 and the driving circuit 20 are applications of the basic circuit composition shown in FIG. For example, resistors Ra and Rb and VR in FIG. 4 is a set of partial pressure sub-circuit, which is the composition of two resistors R ₁₁ and VR ₁ in FIG. 5, two amplifiers OP ₁ in FIG. 4 drives The two buffers 201 in the circuit 20 are used (in actual circuit design, that is, composed of amplifiers).
Reference numeral 4 denotes an externally inputted calibration reference voltage. According to this mode, the design mode of the second set voltage dividing sub-circuit composed of two R ₂₂ and VR ₂ in the resistive voltage dividing circuit 20 and the two buffers 202 and the input terminals 42 and 43 in the driving circuit 20 are changed. As above, and each set of voltage divider sub-circuits uses the same input voltage, e.g., V _CC , which solves the problem of having to input more reference voltages than externally, and The required number of reference voltages can be halved. In addition, by this method, a few sets of basic circuits in FIG. 4 are applied to the voltage dividing circuit 10 and the driving circuit 20 in FIG.

In FIG. 5, if the number of input calibration voltages required by the data driver 30 is 2N (V ₁ , V
₂ ,..., V _2N-3 , V _2N-1 , V _2N ), and through the design of the present embodiment, half of the buffers (eg, V1, V3, V5 ...
(V _2N-3 , V _2N-1 , V _2N buffers) with the data driver 30 is suspended, and other V ₂ , V ₄ , V _6.
... V _2N-2 and V _2N are resistance voltage dividing circuits 10 in the present invention.
In resistor R ₁₁ in multiple sets of partial pressure sub-circuit, R ₂₂ ... and the variable resistor VR _1, VR ₂ divides by ..., as well as the adjustment mode centrosymmetric voltage of the present invention, each set The voltage divider sub-circuits jointly share one external reference voltage (eg, V
_CC ) as well as different resistors (eg, resistors R ₁₁ ,
The combination use of R _22), the variable resistor VR _1, VR ₂ ·
··· Adjustment for the variable resistor VR
_1, VR ₂ In the both ends of ..., a pair of positive and outputs a negative polarity voltage, and direct the data driver 3
It is not necessary to connect to the data driver 30 after connecting to 0 and further to the buffer. Through the design of the present invention, the number of gamma calibration voltages required for external inputs can be reduced to a minimum, and for non-external input calibration voltages can be obtained by using a voltage divider and variable resistor adjustment. Can be. For example, if you need to input 16 gamma calibration voltages including positive and negative polarities, you need to input 4 sets of gamma calibration voltages from outside after implementing the present invention. The four sets of calibration voltages have eight positive and negative polarity voltages, and are connected to eight buffers and then to a data driver. In addition, from the four sets of gamma calibration voltages, eight different positive and negative polarity voltages can be obtained through the variable resistance adjustment, which are directly connected to the data driver. This scheme can effectively reduce the number of required calibration voltage inputs.

[0023]

As can be seen from the present invention, the present invention implements the centrally symmetric voltage on the voltage dividing circuit, thereby obtaining an effective and good adjustment method for the gamma calibration voltage and the gamma correction voltage. The calibration voltage is controlled by an externally input voltage, and a simple, convenient, and elastic control method can be obtained.
In addition, the number of buffers required in the circuit and the number of pins required to input an external gamma calibration voltage can be relatively reduced.

In summary, the features of the structure of the present invention and each of the embodiments are described in detail, and the object of the present invention is sufficiently advanced in terms of function, implementation, and extremely industrial value. And is currently not on the market and in operation and has patent requirements.

However, what has been described above is merely a preferred embodiment of the present invention, and does not limit the scope of the present invention. It belongs to the claims of the present invention.

[Brief description of the drawings]

1A is a diagram showing a relationship between a known image data code (Code) and display characteristics (T) of a display, FIG. 1B is a diagram showing a relationship between voltage (Voltage) and display characteristics (T) of a general liquid crystal display, and FIG. FIG. 4 is a characteristic curve diagram of an ideal image code (Code) versus display characteristics (T) of a liquid crystal display, and D is a conversion curve diagram of a relationship between a data code (Code) and a voltage of a known gamma voltage calibration circuit.

FIG. 2 is a gamma voltage calibration circuit diagram of a well-known fixed proportional resistance division.

FIG. 3 is a diagram showing lightning effect characteristics of a known liquid crystal display voltage drive.

FIG. 4 is a basic circuit diagram of a preferred embodiment of the present invention.

FIG. 5 is an electric circuit diagram of a preferred embodiment in which a data driver is connected to the present invention.

[Explanation of symbols]

1,10 resistor divider 2,20 drive circuit 3, 30 data driver 41, 42, 43, 44 input 201, 202 buffer OP ₁ amplifier VR buffer, VR _1, VR ₂ variable resistors Ra, Rb, R ₁₁ , R ₂₂ resistance

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) H04N 5/202 H04N 5/202 5/66 5/66 A F term (Reference) 2H093 NA51 NA58 NA61 NA80 NC02 NC13 NC14 NC65 ND01 ND04 ND06 ND07 ND08 ND17 ND24 ND36 ND49 ND54 5C006 AF46 AF52 AF83 BB15 BC13 BF43 FA42 FA43 5C021 PA02 PA53 PA95 XA34 5C058 AA06 BA02 BA13 5C080 AA10 BB05 DD01 JJ22 FF03

Claims (8)

[Claims] A driving circuit having a plurality of amplifiers or buffers, the driving circuit receiving a plurality of external reference voltages and outputting it to an external data driver; Is a centrally symmetric gamma voltage calibration circuit that receives the output of the gamma voltage calibration circuit and converts the output result into a set of voltages, wherein the gamma voltage calibration circuit comprises a voltage divider circuit, and the voltage divider circuit , Composed of a few sets of voltage divider sub-circuits, each one of the voltage divider sub-circuits being composed of some number of resistive elements, of which
At least one variable resistance element is included in some of the resistance elements, and by adjusting the variable resistance element, one voltage is output at both ends thereof, and the obtained output result is input to the data driver. A centrally symmetric gamma voltage calibration circuit characterized by being connected to an end. 2. The voltage obtained across the variable resistor is:
2. The centrally symmetric gamma voltage according to claim 1, wherein by adjusting the variable resistor, the voltage value at both ends has a centrally symmetric voltage adjustment mode with respect to an intermediate value of the voltage values at both ends. Calibration circuit. 3. The voltage obtained at both ends of the variable resistance element is a positive or negative polarity voltage of one of a few sets required by the data driver. 2. The centrally symmetric gamma voltage calibration circuit according to 1. 4. When the number of input terminals of the data driver is 2N, the number of output terminals of the driving circuit is N, and the number of output terminals of the voltage dividing circuit is also N. Item 3. A centrally symmetric gamma voltage calibration circuit according to item 1. 5. A centrally symmetric gamma voltage calibration circuit, comprising a driving circuit, a plurality of amplifiers or buffers,
The drive circuit receives a plurality of external reference voltages and outputs a result after the processing. The drive circuit includes a drive circuit and a voltage divider circuit. The sub-circuit is composed of a small number of resistive elements, of which at least one variable resistive element is included in some of the resistive elements, and by adjusting the variable resistive elements, one voltage is provided at both ends thereof. Wherein the output of the driving circuit and the output of the voltage dividing circuit are input terminals of an external data driver, and the data driver outputs the output of the gamma voltage calibration circuit. A centrally symmetric gamma voltage calibration circuit, characterized in that after obtaining the result, it converts it and outputs a few sets of voltages. 6. A voltage obtained at both ends of the variable resistor,
6. The centrally symmetric gamma voltage according to claim 5, wherein the adjustment of the variable resistor causes the voltage value at both ends to be in a centrally symmetric voltage adjustment mode with respect to an intermediate value between the voltage values at both ends. Calibration circuit. 7. The voltage obtained at both ends of the variable resistance element is a positive or negative polarity voltage of one of a few sets required by the data driver. 6. The centrally symmetric gamma voltage calibration circuit according to 5. 8. When the number of input terminals of the data driver is 2N, the number of output terminals of the driving circuit is N, and the number of output terminals of the voltage dividing circuit is also N. Item 6. A centrally symmetric gamma voltage calibration circuit according to item 5.