JP2001242834A - Liquid crystal driving circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce a difference of brightness between a master side driving part and a slave side driving part in a liquid crystal panel. SOLUTION: In a slave side driving part 3, one end potential of a driving potential generation circuit 25 of the master side driving part 2 is supplied to one end of a driving potential generation circuit 35. The driving potential generation circuit 35 generates driving voltages, based on the end potential of the circuit 25. Each driving voltage is supplied to a slave side driving circuit 34 via each operational amplifier.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a liquid crystal drive circuit for driving a liquid crystal panel, and more particularly to a master-slave type liquid crystal drive circuit having a master side drive circuit and a slave side drive circuit.

[0002]

2. Description of the Related Art A simple matrix type liquid crystal panel such as an STN liquid crystal panel has a large number of scanning electrodes (row electrodes) extending in a row direction and a large number of signal electrodes (column electrodes) extending in a column direction. . Then, a row electrode is selected in a time-division manner, a selection voltage is applied to the row electrode, and a voltage corresponding to image data corresponding to the selected row is applied to each column electrode. The row electrode is driven by a row driver and the column electrode is driven by a column driver. The row driver and the column driver are often integrated in one driving IC. Hereinafter, the row driver and the column driver are collectively referred to as a drive circuit.

Further, a method of applying a plurality of levels of voltages to row electrodes and column electrodes when driving a liquid crystal panel is also widely used. Therefore, the drive IC is also provided with a circuit for generating a plurality of levels of drive voltages.

When the display capacity of the liquid crystal panel is large, 1
In some cases, driving cannot be performed by one driving IC.
In such a case, a master using a plurality of drive ICs
A slave method may be used. FIG. 3 is a block diagram showing a master-slave type liquid crystal driving circuit using a plurality of driving ICs 200 and 300 together with the liquid crystal panel 1. In the example shown in FIG. 3, the drive IC 200 drives the upper part 1a of the liquid crystal panel 1, and the drive IC 300 drives the lower part 1b of the liquid crystal panel 1. FIG. 3 shows a driving IC
At 200, a row driver 241 and a column driver 242
Only the row driver 3 in the driving IC 300 is shown.
41 and column driver 342 are shown, but drive I
Other circuits are also mounted on the C200 and C300.

FIG. 4 is a block diagram showing in detail the configuration of a liquid crystal drive circuit when a plurality of drive ICs are used. FIG.
2 shows the master-side drive unit 2 and the slave-side drive unit 301, the master-side drive unit 2 corresponds to the drive IC 200, and the slave-side drive unit 301 corresponds to the drive IC 300.

In the master-side drive section 2, a booster circuit (voltage generating means) 21 includes external capacitors 210 and 21.
The voltage supplied to the driving IC is boosted using the charging voltage of 1. The boosted voltage value is a value larger than the largest one of the plurality of types of driving voltage values. Booster circuit 2
1 is stabilized by the regulator 22.

The output of the regulator 22 is applied to a drive potential generating circuit 25. The driving potential generating circuit 25 includes resistors 250, 251, 252, 253, 25 connected in cascade between the output terminal of the regulator 22 and the ground level.
4 Each resistor 250, 251, 252, 2
The resistance value of 53,254 is such that the voltage at one end is V0, V
1, V2, V3, and V4. The regulator side (high potential side) of both ends of each of the resistors 250 to 254 is connected to the
Operational amplifiers 230, 231, 2 corresponding to 50 to 254
32, 233 and 234 are connected to non-inverting input terminals.
The output of each of the operational amplifiers 230 to 234 is connected to its own inverting input terminal and is also input to the master side driving circuit 24. Each of the operational amplifiers 230 to 234 is used as a non-inverting amplifier having an amplification degree of 1, that is, a voltage follower mainly for impedance conversion.

That is, as shown in FIG. 4, a driving voltage V0-
V5 is supplied. The master-side drive circuit 24 uses six types of voltage values including the voltage values of the drive voltages V0 to V4 and the ground level. Master-side drive circuit 24 includes row driver 241 and column driver 242 shown in FIG. 3, and drives upper portion 1a of liquid crystal panel 1 using six types of voltage values.

The driving voltage V0 is supplied from the operational amplifier 23.
To V4 are capacitors 400 and 40 for voltage stabilization.
The signals are supplied to the slave side driving unit 301 via 1, 402, 403, and 404. In the slave side drive unit 301, the slave side drive circuit 34 includes a row driver 341 and a column driver 342 shown in FIG. 3, and drives the lower part 1b of the liquid crystal panel 1 using six types of voltage values. Although not shown in FIG. 4, a signal for display is also supplied from the master side driving unit 2 to the slave side driving unit 301.

The master side drive unit 2 and the slave side drive unit 30
The use of 1 makes it possible to drive the liquid crystal panel 1 having a specification exceeding the capacity of one drive IC (for example, the number of controllable column electrodes). When the master-side drive unit 2 and the slave-side drive unit 301 are each implemented by one drive IC, the drive voltage is supplied from the master-side drive unit 2 to the slave-side drive unit 301. Thus, the sameness of the driving voltages used by both the driving units is ensured.

When the master-side drive unit 2 and the slave-side drive unit 301 are each implemented by one drive IC, both are generally implemented by the same type of drive IC. Therefore, although the booster circuit 21, the regulator 22, the driving potential generating circuit 25, and the operational amplifier unit 23 physically exist in the slave side drive unit 301, the slave side drive unit 301 is mounted on the liquid crystal drive module. Before these functions are set, they are not used. That is, the drive IC is a programmable IC. Although not shown in FIG. 4, a variable resistor is inserted between the regulator 22 and the driving potential generating circuit 25.

[0012]

In the master-side drive section 2, since a drive voltage for the master-side drive circuit 24 is generated inside the drive IC, the impedance is low, and the operational amplifiers 230 to 234 supply the master-side drive circuit. 24 is supplied with current stably. However, in the slave-side drive unit 301, the amount of current supplied to the slave-side drive circuit 34 becomes unstable due to the wiring resistance of the printed wiring board and the current supply capability of the operational amplifiers 230 to 234 on the master side. . As the display capacity of one of the liquid crystal panels increases, the master-side drive unit 2 and the slave-side drive unit 301
Of the slave side driving circuit 34
The brightness of the lower portion 1b of the liquid crystal panel 1 is reduced due to the instability of the supply current to the liquid crystal panel 1. That is, when the display capacity of the liquid crystal panel 1 becomes larger, the liquid crystal panel 1
In this case, there is a problem that a luminance difference occurs between the master side driving part and the slave side driving part.

The present invention is directed to solving such a problem. In the case where a liquid crystal panel having a relatively large display capacity is driven by using a master side driving section and a slave side driving section, the liquid crystal panel is used. It is an object of the present invention to provide a liquid crystal drive circuit capable of reducing a difference in luminance between a master side drive portion and a slave side drive portion in the above.

[0014]

In a liquid crystal drive circuit according to the present invention, a master side drive section includes a plurality of voltage generation means for generating a voltage which is a source of a drive voltage, and a plurality of voltage generation means based on the voltage generated by the voltage generation means. A master-side driving potential generating means for generating a driving voltage, and a master-side operation for stabilizing the current of a voltage level signal generated by the master-side driving potential generating means and supplying the signal to a master-side driving circuit for driving a liquid crystal panel Amplifying means, wherein the slave-side drive section introduces one of the plurality of drive voltages in the master-side drive section and generates a plurality of drive voltages based on the same, and a slave-side drive potential generation means, And a slave-side operational amplifying means for stabilizing the current of the voltage level signal generated by the slave-side driving potential generating means and supplying it to a slave-side driving circuit for driving the liquid crystal panel. And wherein the door.

The slave-side drive section may include voltage generating means for supplying power to the slave-side operational amplification means. In this case, the current supply capability of the slave-side drive unit increases, and the current supply capability of the master-side drive unit also increases because the master-side drive unit does not need to drive the slave-side operational amplifier. A large-capacity liquid crystal panel can be driven.

In the liquid crystal drive circuit, each of the master-side drive unit and the slave-side drive unit is formed of the same drive IC, and each drive IC sets the master block by setting an unused function block to a disabled state. A configuration in which the side drive unit and the slave side drive unit are formed may be employed.
In that case, the master side drive section can generate a plurality of drive voltages based on one of the plurality of drive voltages in the master side drive section, and can easily use the same IC to achieve the master drive. The drive voltages of the side drive unit and the slave drive unit can be matched.

[0017]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing a first embodiment of a liquid crystal drive circuit according to the present invention, together with a liquid crystal panel 1. The configuration of the master-side drive unit 2 is the same as the configuration shown in FIG. 4, but FIG. 1 clearly shows that a variable resistor 26 is inserted between the regulator 22 and the drive potential generation circuit 25. Have been. The variable resistor 26 is
For example, the resistance value is changed via a control unit in a device in which the liquid crystal drive module is incorporated, and is used to enable the brightness adjustment of the liquid crystal panel 1 to be performed artificially.

In this embodiment, the slave driving unit 3
, A driving potential generating circuit 35 and an operational amplifier 33 are used. One side of the driving potential generating circuit 35 (the side opposite to the ground) and one side of the driving potential generating circuit 25 in the master side drive unit 2 (the side opposite to the ground).
Is supplied via a potential supply line 601. This potential is equal to the driving voltage V0. The driving power for the operational amplifier 33 of the slave driver 3 is supplied from the booster circuit 21 of the master driver 2.

The driving potential generating circuit 35 includes resistors 350 and 3 cascaded between the level of V0 and the ground level.
51, 352, 353, and 354. The resistance value of each resistor 350, 351, 352, 353, 354 is
Each resistor 250, 251,
252, 253, 254. Therefore, the voltage at the end of each of the resistors 350, 351, 352, 353, 354 is equal to the voltage of each resistor 250,
251, 252, 253, and 254.

The high-voltage side of both ends of each of the resistors 350 to 354 is supplied to the operational amplifier 33 by the resistors 350 to 354.
The operational amplifiers 330, 331, 332 corresponding to 354
333 and 334 are connected to non-inverting input terminals. The output of each of the operational amplifiers 330 to 334 is connected to its own inverting input terminal and is also input to the slave side driving circuit 34. Each operational amplifier 33 in the operational amplifier 33
0, 331, 332, 333, 334 are output from capacitors 500, 501, 502, 504 for voltage stabilization.
504 is connected to the ground level. Each of the operational amplifiers 330 to 334 is used as a non-inverting amplifier having an amplification degree of one.

According to such a configuration, in the slave side driving section 3, the driving voltages V0 to V4 are supplied to the slave side driving circuit 34 via the operational amplifiers 330, 331, 332, 333 and 334. . Therefore, a stable current is supplied to the slave side drive circuit 34, and the liquid crystal panel 1
Of the lower portion 1b of the pixel is prevented from deteriorating. Further, the potential supply line 601 causes the potential of V0 in the slave-side drive unit 3 to be equal to the potential of V0 in the master-side drive unit 2. Therefore, it is guaranteed that the voltage value of each drive voltage in the master side drive unit 2 and the voltage value of each drive voltage in the slave side drive unit 3 are equal.
Therefore, it is possible to prevent the occurrence of a luminance difference due to a difference in the drive circuit between the upper part 1a and the lower part 1b of the liquid crystal panel 1.

The master-side drive unit 2 and the slave-side drive unit 3 are realized by the same type of drive IC. Accordingly, although the booster circuit 21 and the regulator 22 physically exist in the slave-side drive unit 3, the functions are not used before the slave-side drive unit 3 is mounted on the liquid crystal drive module. Is set.

FIG. 2 shows a second embodiment of the liquid crystal driving circuit according to the present invention.
FIG. 2 is a block diagram showing an embodiment of the present invention together with a liquid crystal panel 1. As shown in FIG. 2, in this embodiment, the operating power for the operational amplifier 33 in the slave-side drive unit 30 is supplied from a booster circuit 31 provided in the slave-side drive unit 30. Therefore, the slave side drive unit 30
, Boosting capacitors 310 and 311 are externally provided. The configuration of the booster circuit 31 is the same as the configuration of the booster circuit 21 on the master side. Other configurations are the same as those of the first embodiment.

According to such a configuration, the operational amplifier 33
Is supplied from its own booster circuit 31.
The booster circuit 21 of the master side drive unit 2 is connected to the slave side drive unit 3
It is not necessary to supply power to the 0 operational amplifier 33. Therefore,
If the current supply capability of the booster circuit 21 of the master-side drive circuit 2 becomes insufficient with the use of the first embodiment, such a configuration is preferably used.

Also in this embodiment, the potential supply line 60
Due to 1, the potential of V0 in the slave side drive unit 3 becomes equal to the potential of V0 in the master side drive unit 2. Therefore, it is guaranteed that the voltage value of each drive voltage in the master side drive unit is equal to the voltage value of each drive voltage in the slave side drive unit 3. As a result, the driving voltage V0 used in the slave driver 30
To V4 are equal to the voltage values of the driving voltages V0 to V4 used in the master drive unit 2. That is, even when the configuration as in this embodiment is used, the upper portion 1a and the lower portion 1b of the liquid crystal panel 1 are driven using the same driving voltage on the master side and the slave side, and The lower part 1b is driven with a stable current on the side.

The master-side drive unit 2 and the slave-side drive unit 30 are realized by the same type of drive IC. Therefore,
Although the regulator 22 physically exists in the slave-side drive unit 30, it is set so that those functions are not used before the slave-side drive unit 30 is mounted on the liquid crystal drive module.

As described above, in each of the above embodiments, in the liquid crystal driving circuit for driving the liquid crystal panel 1 in the master-slave method, each driving voltage is supplied to the slave side driving circuit 34 with a stable current. It is configured to be supplied. At this time, the configuration is such that the potential of V0 on the master side matches the potential of V0 on the slave side.
To V4 and the driving voltages V0 to V of the slave side driving circuit 34
4 is guaranteed to match each other.

In the above-described embodiments, one slave-side drive unit 3 or 30 is used. However, the present invention can be applied to a case where two or more slave-side drive units are used.
Further, the master-side drive unit 2 and the slave-side drive units 3 and 3
Although the case where one drive IC is used as 0 is described, the present invention can also be applied to a case where the master side drive unit 2 and the slave side drive units 3 and 30 are realized by individual circuits.

[0029]

As described above, according to the present invention, the liquid crystal driving circuit allows the slave-side driving section to control the plurality of driving voltages based on one of the plurality of driving voltages in the master-side driving section. , And amplify the generated signal of each voltage level and supply the amplified signal to the slave drive circuit that drives the liquid crystal panel. Therefore, the brightness of the master drive portion and the slave drive portion in the liquid crystal panel is increased. There is an effect that the difference can be reduced.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a first embodiment of a liquid crystal driving circuit.

FIG. 2 is a block diagram showing a second embodiment of a liquid crystal driving circuit.

FIG. 3 is a block diagram showing a master-slave type liquid crystal driving circuit.

FIG. 4 is a block diagram showing a conventional liquid crystal drive circuit.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 liquid crystal panel 2 master-side drive unit 3 slave-side drive unit 21, 31 booster circuit (voltage generating means) 22 regulator 23, 33 operational amplifier unit 24 master-side drive circuit 25, 35 drive potential generation circuit 34 slave-side drive circuit

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 2H093 NA10 NA22 NA32 NA33 NA80 NC10 NC13 NC16 NC22 NC24 NC26 NC90 ND09 ND37 ND39 NE07 NF13 5C006 BB12 BB14 BF43 BF46 FA22 FA37 5C080 AA10 BB05 BB06 DD03 DD05 DD25 FF03JJ02

Claims (3)

[Claims] 1. A liquid crystal drive circuit for driving a liquid crystal panel in a master-slave system using a master side drive section and a slave side drive section, wherein the master side drive section generates a voltage which is a source of a drive voltage. Voltage generating means, a master-side driving potential generating means for generating a plurality of driving voltages based on the voltage generated by the voltage generating means, and a current-stabilizing signal of the voltage level generated by the master-side driving potential generating means. And a master-side operational amplifier that supplies a master-side drive circuit that drives a liquid crystal panel, wherein the slave-side drive unit introduces one of a plurality of drive voltages in the master-side drive unit. Based on this, a slave-side drive potential generating means for generating a plurality of drive voltages and a voltage-level signal generated by the slave-side drive potential generator are current-stabilized to provide a liquid crystal display. Liquid crystal drive circuit, characterized in that a slave operational amplifier means for supplying to the slave side drive circuit for driving the panel. 2. The slave-side drive section includes a voltage generator for supplying power to the slave-side operational amplifier.
Liquid crystal drive circuit as described. 3. The master-side drive section and the slave-side drive section are each formed of the same drive IC.
3. The liquid crystal drive circuit according to claim 1, wherein the master drive unit and the slave drive unit are formed by setting an unused function block to a use prohibited state.