KR930002515Y1 - Circuit for driving liquid crystal display device - Google Patents

Abstract

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Description

Driving circuit of liquid crystal display device

1 is a driving circuit diagram of a conventional liquid crystal display device using an emitter follower.

2 is a driving circuit diagram of a liquid crystal display device according to the present invention.

* Explanation of symbols for main parts of the drawings

R ₁ , R ₂ : resistor element TR ₁ , TR ₂ : transistor

R ₃ , R ₄ : resistance

The present invention relates to a driving circuit of a liquid crystal display (LCD), and in particular, to maintain a constant driving voltage value of the liquid crystal display by a transistor circuit having a diode characteristic to improve the scattering luminance characteristics of the liquid crystal display. It relates to a driving circuit of a liquid crystal display device independent of temperature change

Conventionally, the driving circuit of the liquid crystal display device applies an input voltage Vo to the base, draws out the output Vo 'from the emitter, as shown in FIG. 1, and applies the liquid crystal display device power supply V _{EE to the} collector. Using a emitter follower (collector grounding circuit) connected to, the voltage gain is close to 1, and the output voltage characteristics of the buffer in which the fluctuation of the base voltage and the emitter load voltage are the same. While driving the liquid crystal display device, the positive polarity applied voltage (Vcc) shown in the drawing is applied to the liquid crystal display device, and the voltage is configured to draw the required power supply of the liquid crystal display device through the respective bias resistors connected in series. It is.

However, this is because the liquid crystal display is driven using the voltage gain and buffer buffer characteristics of the emitter follower, but the collector current of the drive transistor transistor TR is applied to the applied voltage V _EE of the liquid crystal display. (Ico) changes proportionally according to the temperature change from room temperature to high temperature or from room temperature to low temperature, and emitter output voltage value (Vo ′) is not constant. Therefore, the display quality state of the liquid crystal display device cannot be maintained. In addition, the scattering luminance characteristic of the liquid crystal display device is degraded, and as the number of scanning electrodes of the liquid crystal display device increases, data indicating the display quality is applied to a non-selection point of an undesired portion, and so-called cross-talk phenomenon occurs. There were many problems such as becoming.

Therefore, the present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is to compensate the temperature of the liquid crystal display device to maintain a constant output voltage value for the applied voltage of the liquid crystal display device at a high temperature and a low temperature. An object of the present invention is to provide a driving circuit of a liquid crystal display device capable of improving the scattering effect of unique characteristics and further improving the display quality of the liquid crystal display device.

Hereinafter, the configuration and operation effects of the present invention will be described in detail with reference to the illustrated drawings.

In order to achieve the above object, a driving circuit of a liquid crystal display device according to the present invention is a driving circuit of a conventional liquid crystal display device which drives an applied voltage of a liquid crystal display device by one transistor which is a characteristic of an emitter follower. A temperature compensating means comprising two resistance elements (R1) and (R2) for compensating the resistance temperature characteristic by combining the applied voltage of the display element with a positive or negative resistor having a constant resistance-temperature characteristic and a semi-fixed resistance; Two transistors TR1 and TR2 having a diode characteristic for outputting a driving voltage of a predetermined liquid crystal display element by means of a compensation means.

Hereinafter, with reference to the accompanying drawings will be described the operation of the present invention.

FIG. 2 is a circuit diagram of the present invention that maintains a constant current between collector currents of a driving power supply of a liquid crystal display device regardless of temperature change. (R1) and (R2) are semi-fixed with, for example, a transistor or a transistor. A resistance element as a temperature compensating means in which resistances are combined to have a degradation temperature characteristic, (V _EE ) is one applied voltage required for a liquid crystal display device, (Vo) is an input voltage of a subselect point, and (IC ₁ ) IC ₂ is a collector current of transistors TR1 and TR2 that are temperature-compensated through each of the resistance elements R ₁ and R ₂ having resistance temperature characteristics, and IB ₁ IB ₂ is a liquid crystal display device. The output voltage of transistors TR1 and TR2 ignoring the resistance values of the resistors R ₁ (R ₂ ) and another resistor R ₃ (R ₄ ) with respect to the applied voltage V _EE of It is an output driving voltage applied to the liquid crystal display while maintaining a constant value despite the change.

The transistor TR ₁ and the transistor TR ₂ constitute a transistor circuit having a diode characteristic, and this transistor circuit has an emitter follower characteristic, and thus has a buffer characteristic in which a voltage gain is substantially close to one. .

In this state, the positive polarity applied voltage (Vcc) of the liquid crystal display device is normally applied to the liquid crystal display device at 5V, and the applied voltage (V _EE ) of the liquid crystal display device is the negative voltage, which is usually about -21V to -23V. It is applied to the drive circuit of the display element.

At this time, the negative voltage V applied to the liquid crystal display element is set to be greater than the signal input voltage Vo serving as the base potential of the transistor TR ₁ , which can be arbitrarily varied.

In addition, the input voltage Vo is a simulation voltage, which is not necessary for the actual driving of the liquid crystal display element.

In addition, the current of the transistors TR ₁ and TR ₂ is applied to the current voltage V _EE of the liquid crystal display device whose temperature is compensated by the resistance element R ₁ having the resistance temperature characteristic of the current I _B1 and I _B2 . This is a bias current which is applied to the bases of the transistors TR ₁ and TR ₂ as currents drawn through the respective resistors R ₃ and R ₄ close to zero, and drives these transistors.

On the other hand, the applied voltage (V _EE ) of the liquid crystal display is divided into two resistors R ₁ (R ₂ ) having a resistance temperature characteristic, and the collector layer resistance element of the transistor TR ₁ having a diode characteristic ( R ₁ ) is set such that the compensation time and capacitance value of the resistance temperature characteristic are smaller than that of the collector side resistor element R ₂ of the transistor TR ₂ which drives the applied voltage V _EE of the temperature compensated liquid crystal display device.

Thus, if the base of the transistor (TR _2), the resistance (R ₄₎ is applied to the I _B2 flowing through, the base of the transistor (TR ₁₎ it is I _B1 flowing through the resistor (R _3), a high temperature or room temperature from room temperature Each transistor TR ₁ corresponding to the point in time at which the applied voltage V _EE of the liquid crystal display element is changed from a low temperature to a low temperature by a resistance element R ₁ (R ₂ ) having resistance temperature characteristics at room temperature. by compensation in accordance with the collector current (I _{C1) (C2} I) of (TR ₂₎ temperature to be applied to each side of the collector of the transistor (TR _1), a transistor (TR _1).

Therefore, the collector and the base of each of the transistors TR ₁ and TR ₂ are equipotential to each other to turn on and output the applied voltage V _EE of the temperature compensated liquid crystal display to the emitter.

Represents the above-described relationship in the formula, TR ₁ = TR _2, a transistor (TR ₁₎ and the respective base-emitter voltages (V _BE1) (V _BE2) of (TR ₂₎ is shown.

Therefore, by using the same base voltage of each transistor TR ₁ (TR ₂ ) through the resistance element R ₁ having the resistance temperature characteristic, I _B I _B1 = I _B2 .

The collector current I _C1 of each of the transistors TR ₁ and TR ₂ , which is based on the above equation, is given by the following formula.

It becomes

Here, the applied voltage (V _EE) is a transistor (TR ₁₎ base-emitter voltage (V _EE) greater than the applied voltage (V _EE) a resistance-temperature characteristic of the liquid crystal display of (TR ₂₎ in the liquid crystal display device The value of the current (I _C1 ) divided by the excited resistance element (R ₁ ) is Greater than the value

therefore, Becomes

In other words, the applied voltage V _EE required for the liquid crystal display device compensates for the changed temperature when the temperature is changed from normal temperature to high temperature or normal temperature to low temperature by the resistance element R1 having the resistance temperature characteristic. The transistor TR ₁ is connected to a transistor TR ₂ that drives the applied voltage V _EE of the liquid crystal display element temperature compensated by the resistance element R ₂ to the liquid crystal display element, thereby collecting the collector of the transistor TR ₂ . The current I _C2 is maintained at a stable value irrespective of temperature change and supplied to the liquid crystal display.

On the other hand, while the positive voltage Vcc of the liquid crystal display device is applied to the liquid crystal display device, the voltage is drawn to the required power supply of the liquid crystal display through respective bias resistors connected in series, and the final stage of the bias resistor is In this case, the voltage falls to a value almost equal to one applied voltage (V _EE ) required for the liquid crystal display, and compensates for the output voltage (Vo ′) reduced by temperature change by the driving circuit of the liquid crystal display. do.

As described above, according to the present invention, a resistor or a transistor and a semi-fixed resistor are combined to have a resistance temperature characteristic, and a transistor circuit having a diode characteristic constitutes a high temperature at room temperature or a low temperature at room temperature. Therefore, even if there is a temperature change, one of the applied voltages required for the liquid crystal display device is kept constant by the resistor or the resistor and the resistor and the semi-fixed resistor combined with the semi-fixed resistance to have the resistance temperature characteristics, thereby inherent liquid crystal display It can not only widen the display quality area of the device, but also improve the temperature field, and can prevent the malfunction of the display quality caused by the minute difference in driving voltage required for the liquid crystal display device. .

Claims (1)

The emitter in a normal of the drive circuit of a liquid crystal display device drive, the applied voltage (V _EE) of the liquid crystal display element by a transistor (TR) the nature of the follower, the applied voltage (V _EE) of the liquid crystal display device Is a temperature compensating means comprising two resistive elements (R ₁ ) (R ₂ ) for compensating for resistance temperature characteristics by combining a resistor or a resistor with a semi-fixed resistor, and a liquid crystal display kept constant by the silver compensating means. _2. A driving circuit for a liquid crystal display device, characterized in that it comprises two transistors (TR ₁ ) (TR ₂ ) having a diode characteristic for outputting a driving voltage (Vo ') of the device.