KR0182033B1 - Voltage split circuit of liquid-driving integrated circuit - Google Patents

Abstract

The present invention relates to a voltage division circuit of a liquid crystal driving integrated circuit capable of variously outputting output voltage levels of a color liquid crystal driving integrated circuit using only a layout contact.

The configuration of the present invention comprises: a first amplifier receiving a first input voltage, amplifying it, and outputting a lowest voltage; A second amplifier which receives the second input voltage, amplifies it, and outputs the highest voltage; A plurality of resistors are connected in series between the first amplifier and the second amplifier to output a plurality of divided output voltages at each node.

The effect of the present invention is that the voltage level output from the driver integrated circuit which generates the liquid crystal driving voltage through the voltage division circuit can be variously output using only the contact at the time of layout, so that the voltage level of the light transmittance is transferred to another module. It is possible to provide a voltage division circuit and a layout of a liquid crystal driving integrated circuit that can be easily extended.

Description

Voltage division circuit of liquid crystal drive integrated circuit

1 is a conventional voltage division circuit,

2 is a layout of a conventional voltage division circuit,

3 is a voltage division circuit according to an embodiment of the present invention.

4 is a layout of a voltage division circuit according to an embodiment of the present invention.

5 is a graph showing the relationship between the light transmittance and the voltage according to the embodiment of the present invention,

6 is a layout of a voltage division circuit according to an embodiment of the present invention in which a select contact is added in a conventional voltage division circuit.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a voltage division circuit of a liquid crystal drive integrated circuit. In particular, the output voltage levels of a color liquid crystal drive integrated circuit can be variously output by using a contact at the time of layout. The present invention relates to a voltage division circuit.

Hereinafter, with reference to the accompanying drawings, a conventional voltage division circuit and layout will be described.

1 is a conventional voltage division circuit, and FIG. 2 is a layout of a conventional voltage division circuit.

As shown in FIG. 1, the conventional voltage divider circuit has nine input voltages VI _{1 ... 9} and 64 resistors R _{1 ... 64 in} the case of 64 gradations. Comprising 64 divided output voltages (V _{1 ... 64} ), the first input voltage (VI ₁ ) becomes the first divided output voltage (V ₁ ), the first input voltage (VI ₁ ) and the second Eight resistors R _{1 ... 8} are connected in series between the input voltage VI ₂ , and eight split output voltages V _{1 ... 8} are output at the node between each resistor and resistor. In addition, the same configuration exists between the remaining input voltages VI _{2... 9} , the resistors R _{9 ... 64} , and the split output voltages V ₉ . 2 is a layout of the voltage division circuit of FIG. 1, in which 65 contacts 22 are formed on the polysilicon resistance region 21, and the divided output voltages V1 at each contact are shown _{. ..64} ).

The operation of the voltage division circuit of the conventional liquid crystal drive integrated circuit according to the above configuration is as follows.

When 64 gradations are used in the liquid crystal driving integrated circuit, one pixel can express 64 × 64 × 64 = 262,144 by three colors of red, green, and blue. For example, when the first divided output voltage V ₁ is set at 1 V and the 64 divided output voltage V ₆₄ is configured at 64 V at 1 V intervals, the first divided output voltage V ₁ is dark when only red is expressed. If the red, the 64th divided output voltage (V ₆₄ ) can represent a pale red color, respectively, between the first divided output voltage (V ₁ ) and the 64th divided output voltage (V ₆₄ ) in between can be represented by a slightly blurred red. Will be. The voltage division circuit of the conventional liquid crystal drive integrated circuit uses nine input voltages (VI _{1 ... 9} ) to divide and output 64 voltages, and connects eight resistors in series to each of the resistors. The split output voltage is output between the nodes, and only the fixed split output voltage is output as originally designed. That is, in the layout, 65 contacts 22 are formed on the polysilicon resistance region 21 so that diffusion resistors 23 are formed between the contacts 22. Only one split output voltage is output to the contact 22.

However, in the conventional color liquid crystal drive integrated circuit, the output of the driver integrated circuit for the color liquid crystal drive is expressed as a voltage level for making the color red or green for the three colors of red, green, and blue. However, for example, in a 64-layer thin film transistor (TFT) integrated circuit, a voltage of 64 levels is output, and the relationship between the light transmittance and the voltage does not appear proportionally in all liquid crystals. As the ratio of light transmittance and voltage level is slightly different, normal colors can be used only in modules having the same light transmittance characteristics when the split output voltages of the integrated circuits are constant, but normal colors are used in modules having the same light transmittance characteristics. This difficulty is problematic in that the utilization of integrated circuits cannot be extended. That is, when the module is changed, there is a problem that the color may not be expressed with each of the divided output voltages.

Therefore, an object of the present invention is to solve the above-mentioned problems, so that the voltage level output from the driver integrated circuit that generates the liquid crystal drive voltage through the voltage division signal can be variously output using only the contact at the time of layout. To provide a voltage division circuit and layout of a liquid crystal drive integrated circuit that can easily extend the voltage level of the light transmittance to other modules.

As a means for achieving the above object, a configuration of the present invention comprises: a first amplifier for receiving a first input voltage, amplifying it, and outputting a lowest voltage; A second amplifier which receives the second input voltage, amplifies it, and outputs the highest voltage; A plurality of resistors connected in series between the first and second amplifiers to output a plurality of divided output voltages at each node; Consists of

The layout of the voltage division circuit may include: a first amplifier which receives the first input voltage, amplifies it, and outputs the lowest voltage; A second amplifier which receives the second input voltage, amplifies it, and outputs the highest voltage; A plurality of metals comprising contacts receiving the output voltages of the amplifiers, a plurality of main contacts for outputting a plurality of split output voltages, and a plurality of select contacts for outputting a plurality of split output voltages selected by a user. Silicon resistive region; Consists of

In the conventional voltage division circuit, a voltage division circuit in which only selective contacts are added includes a plurality of metals on the polysilicon resistance region, and a plurality of divided output voltages having main contacts and selection contacts in each metal region. To select and print.

Referring to the accompanying drawings, the most preferred embodiment which can easily implement this invention by the above structure is as follows.

3 is a voltage division circuit according to an embodiment of the present invention.

4 is a layout of a voltage division circuit according to an embodiment of the present invention.

5 is a graph showing the relationship between the light transmittance and the voltage according to the embodiment of the present invention,

6 is a layout of a voltage division circuit according to an embodiment of the present invention in which a select contact is added in a conventional voltage division circuit.

As shown in FIG. 3, the configuration of the voltage division circuit according to the embodiment of the present invention includes a first amplifier 31 that receives the first input voltage VI ₁ , amplifies it, and outputs the lowest voltage. ; A second amplifier 32 that receives the second input voltage VI ₉ , amplifies it, and outputs the highest voltage; A plurality of resistors R _{1 ...} connected in series between the first amplifier 31 and the second amplifier 32 to output a plurality of divided output voltages V _{1 ... 64} at each node _{. 64} ); Consists of

The layout of the voltage division circuit according to the embodiment of the present invention also includes: a first amplifier 31 which receives the first input voltage VI ₁ , amplifies it, and outputs the lowest voltage; A second amplifier 32 that receives the second input voltage VI ₉ , amplifies it, and outputs the highest voltage; A plurality of main contacts 42 for outputting a plurality of divided output voltages V _{1 ...} A polysilicon resistance region 21 composed of a plurality of metals 41 surrounding a plurality of option contacts 43 for outputting voltages V ₁ . Is done.

In addition, the layout of the voltage division circuit according to the embodiment of the present invention in which only the contact selection is added to the conventional voltage division circuit receives nine input voltages, and the 65 metals 43 on the polysilicon resistance region 21 are provided. ), And a plurality of divided output voltages (V _{1 ... 64} ) are output by making a main contact 41 and a plurality of select contacts 42 on each metal.

The operation of the voltage division circuit according to the embodiment of the present invention by the above configuration is as follows.

First, referring to FIG. 5, the characteristics of the liquid crystal driving integrated circuit can be represented by the ratio between the light transmittance and the voltage. In the case of the 64 gray level split output voltage, the voltages do not all have the equipotential difference between them. Therefore, the potential difference between the divided voltages of the upper level and the lower level is smaller than the potential difference at the intermediate level. That is, at low and high voltages, the light transmittance is sudden, so the potential difference between them (V ₁ -V ₂ , V ₂ -V ₃ , or V ₆₃ -V _64, etc.) It becomes smaller than the difference (V _10- V ₁₁ , V _40- V _41, etc.).

In addition, referring to FIG. 3, the first input voltage VI ₁ is input to output the minimum voltage necessary for the circuit by the first amplifier 31, and the second input voltage VI ₉ is input to generate the minimum input voltage. The two amplifiers 32 output the highest voltages needed in the circuit. The two amplifiers 31 and 32 are designed to stably output 64 divided output voltages at the node between the 64 resistors and each resistor. Large output current should flow. That is, the two amplifiers 31 and 32 are amplifiers that amplify the input voltage to a large output current. The two amplifiers 31 and 32 need to reduce several input stages and supply only two input voltages. Here, referring to FIG. 4, in the actual layout, the layout position corresponding to each node is a contact, and the layout position corresponding to the resistance is composed of a diffusion resistor between the contact and the contact, respectively. A split output voltage (V _{1 ... 64} ) is output from the contact of the circuit. The 63 metals 41 are formed on the polysilicon resistance region 21, and the main contact 42 is selected on the metal 41. By arranging the contacts 43, if the desired color expression cannot be achieved with the divided output voltages V _{1 .. 64} at each main contact 42, the divided output voltages V ₁ from the selected contact 43 are not provided _{. .64} ), or if the resistance needs to be adjusted, i.e., the split output voltage (V1 _{... 64} ) by the main contact 42 can be adjusted accordingly. In other words, when the ratio of the light transmittance and the voltage level is not appropriate in the module of the liquid crystal drive integrated circuit, the desired voltage level can be obtained by additionally arranging the selection contacts 43 which can change the voltage level.

As a result, the voltage of each level is selected and selected from the main contact 42 and the select contact 43 on the polysilicon resistance region 21, and the voltages of the highest and the lowest two levels are placed instead of the conventional multiple input voltages. By inputting through the amplifiers 31 and 32, the number of input stages can be reduced to two. 6 illustrates arranging a plurality of metals 41 in a layout of a conventional voltage division circuit, and additionally arranging a main contact and a select contact 42 on the plurality of metals 41 to output divided output voltages. For this purpose, it can be seen that the potentials are different when the selection contact 42 is used and when the selection contact 42 is not used. In other words, when the user wants to have a different level of characteristic voltage, it is shown that the conventional integrated circuit can be easily used by changing only the select contact.

Therefore, the effect of the present invention operating as described above is that from the driver integrated circuit which generates the liquid crystal driving voltage through the voltage division circuit by outputting the output voltage levels of the color liquid crystal driving integrated circuit using only the contacts in the layout. The output voltage level may be variously output by using only a contact at the time of layout, thereby providing a voltage division circuit and a layout of the liquid crystal driving integrated circuit which can easily extend the voltage level of the light transmittance to other modules.

Claims (2)

1. A voltage division circuit of a liquid crystal drive circuit, comprising: a first amplifier for receiving a first input voltage, amplifying it, and outputting a minimum voltage; A second amplifier which receives the second input voltage, amplifies it, and outputs the highest voltage; A plurality of resistors connected in series between the first amplifier and the second amplifier and outputting a plurality of divided output voltages at each node, wherein the first amplifier and the second amplifier convert the input voltage into a large output current. And converting the plurality of divided output voltages into one of a main contact and a selected contact in layout. In the layout of the voltage division circuit of the liquid crystal driving circuit, a plurality of metals may be provided on the polysilicon resistance region, and a main contact and selection contacts may be provided in each metal region to select and output a plurality of divided output voltages. A layout of a voltage division circuit of a liquid crystal drive circuit, characterized by the above-mentioned.