JPS6368819A - Generating circuit for liquid crystal driving voltage - Google Patents

Abstract

PURPOSE:To reduce adjustment places and to easily adjust a bias ratio and a voltage level by dividing a DC source voltage by a voltage dividing circuit and generating one or two reference voltages, and amplifying the reference voltages by a circuit composed of a noninverting amplifier and an inverting amplifier in combination and generating plural liquid crystal driving voltages. CONSTITUTION:The (-) terminal of a DC electrode E is grounded and the series circuit of a variable resistance R1 and a resistance R2 is connected between the (+) terminal and the ground to apply the divided voltage between the variable resistance R1 and resistance R2 to the (+) terminal of a differential amplifier A1. This differential amplifier A1 is grounded at the (-) terminal through a resistance Ra and a resistance Rb for feedback is connected between the output terminal and (-) terminal to constitute the noninverting amplifier. Here, the DC source voltage is divided by the voltage dividing circuit to generate one or two reference voltages, which are amplified by the circuit composed of the noninverting amplifier and inverting amplifier in combination, thereby generating plural liquid crystal driving voltages V4. Consequently, adjustment places are reduced and the bias ratio and voltage level are easily adjusted.

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to a liquid crystal drive voltage generation circuit in a time division drive method for a liquid crystal display device.

[Prior Art and its Problems] A liquid crystal drive voltage generation circuit in a time-division drive system of this type of conventional liquid crystal display device is configured as shown in FIG. In FIG. 7, El and R2 are DC power supplies, and the DC power supplies El and R2 are connected in series, and a series circuit of resistors R1 to R6 is connected in parallel between both ends thereof. That is, the resistors R1 to R6 cause the DC power source E1 to
, R2 are divided to obtain a plurality of reference voltages. In this case, one side terminal of the DC power source E1, the + side terminal of R2, and the connection point between the resistors R3 and R4 are all grounded.

In addition, resistors R1, R3, R4, and R6 are variable resistors, and R1
and RB, R3 and R4 are linked to each other so that the resistance value can be varied. Then, the divided voltages across the resistor R2 are applied to the liquid crystal drive voltages Vl and V2 via the differential amplifiers AI and A2, respectively, and the resistor R3
The divided voltage between R4 and R4 is directly used as the liquid crystal drive voltage V3, and the divided voltage across the resistor R5 is applied to the liquid crystal drive voltages V4 and V through differential amplifiers A3 and A4, respectively.
It is often listed as 5. The differential amplifier At-A4 has an output signal fed back to one terminal, and constitutes a voltage follower.

In the above configuration, the liquid crystal drive voltages V1, V2, V4, and 5 are initially set to appropriate values by resistor division as shown in FIG. However, rV1moV5J, rV2
=-V4J. And interlocking variable resistors R1, R
By varying R6, R3, and R4, the voltage level is adjusted so that an optimal bias ratio and potential can be obtained.

However, in the conventional liquid crystal drive voltage generation circuit described in 1-1, there are many variable resistors, and multiple reference voltages corresponding to each liquid crystal drive voltage are generated by resistor division, making adjustment difficult. There was.

[Objective of the Invention] 5. The present invention has been made in view of the above-mentioned circumstances, and provides a liquid crystal drive voltage that can easily adjust the bias ratio and voltage level by reducing the number of adjustment points, and can also perform temperature compensation. The purpose is to provide a generating circuit.

[Summary of the Invention] The present invention divides a DC power supply voltage using a voltage divider circuit to generate one or two reference voltages, and amplifies this reference voltage using a circuit that combines a non-inverting amplifier and an inverting amplifier. It is designed to generate a plurality of liquid crystal driving voltages.

Further, in the present invention, a thermistor is connected in parallel to the voltage dividing resistor of the voltage dividing circuit to perform temperature compensation.

[First Embodiment of the Invention] An embodiment of the present invention will be described below with reference to the drawings. In FIG. 1, E is a DC power source, one terminal of which is grounded, and a series circuit of a variable resistor R1 and a resistor R2 is connected between the terminal and the ground. Then, the divided voltage between the iJ variable resistor R1 and the resistor R2 is input to the child terminal of the differential amplifier A1. This differential amplifier A1 has one terminal grounded via a resistor Ra, and a feedback resistor Rb is connected between the output terminal and one terminal to constitute a non-inverting amplifier. The amplification factor is determined by Rb.

Then, the output signal of the differential amplifier A1 is taken out as the liquid crystal drive voltage Vl, and is inputted to one terminal of the differential amplifier A2 via the resistor RC.

This differential amplifier A2 has a child terminal grounded and a feedback resistor Rd connected between the output terminal and one terminal to form an inverting amplifier, and the amplification factor is determined by the resistors Rc and Rd. Ru. And this differential amplifier A2
The output is output as the liquid crystal drive voltage v5.

On the other hand, the output terminals of the differential amplifier AI are connected to the resistors R3 and R
4 in series to ground, and the voltage generated at the connection point between resistors R3 and R4 is input to the + terminal of differential amplifier A3.

This differential amplifier A3 has an output signal fed back to one terminal, and constitutes a non-inverting voltage follower. Then, the output of this differential amplifier A3 is taken out as the liquid crystal drive voltage v2.

Further, the output of the differential amplifier A3 is inputted to one terminal of the differential amplifier A4 via a resistor Re.

This differential amplifier A4 has a child terminal grounded and a feedback resistor Rf connected between the output terminal and one terminal to form an inverting amplifier, and a resistor Re'-Rf
The amplification factor is determined by And the differential amplifier A
4 is taken out as the liquid crystal drive voltage v4.

Next, the operation of the above embodiment will be explained. The DC power supply E is voltage-divided by a variable resistor R1 and a resistor R2, and the divided voltage is supplied to the differential amplifier At as a reference voltage. In this case, the reference voltage can be arbitrarily set by varying the variable resistor R1. The differential amplifier A amplifies the reference voltage divided by the resistors R1 and R2 with the same polarity and a magnification determined by the value of the resistor Ra5Rb, and outputs it as a liquid crystal drive voltage v1. , are input to the differential amplifier A2 via the resistor Re.

This differential amplifier A2 inverts the polarity of this human power, amplifies it by a magnification determined by the values of the resistors Re and Rd, and outputs it as a liquid crystal drive voltage V5. Therefore, this liquid crystal drive voltage V5 is located at a level (-potential) that is symmetrical to the liquid crystal drive voltage v1 with respect to the ground potential (=V3).

Further, the output of the differential amplifier A1 is voltage-divided by resistors R3 and R4 and input to the differential amplifier A3.

20 Differential amplifier A3 outputs a voltage of the same polarity as the liquid crystal drive voltage v2 with respect to the above-mentioned divided voltage input, and resistor R
It is input to the differential amplifier A4 via e. This differential amplifier A4 inverts the polarity of the input voltage and amplifies it by a factor determined by the values of the resistors Re and Rf.
Output as liquid crystal drive voltage v4. This liquid crystal driving voltage v
4 is the ground potential (=, V, 3
) is located at a symmetrical level (-level).

As described above, the liquid crystal drive voltages Vl, V2, V4, V
5 is obtained, but in order to obtain a constant bias ratio as shown in Figure 2, r'V1 = -V5 and rV2 = -V4
It is J. Therefore, inverting amplifiers A2 and A4 are "-1"
It is a double amplifier, and the resistance RC% Rd % Re s
Rf is rRc=RdJ, rRe=RfJ. That is, the inverting amplifier A2 outputs the liquid crystal driving voltage 5 whose polarity is simply inverted with respect to the liquid crystal driving voltage V1, and
The difference i amplifier A4 outputs a liquid crystal drive voltage v4 whose polarity is simply inverted with respect to the liquid crystal drive voltage v2. The liquid crystal drive voltage v1 is maintained at a constant bias ratio by resistors R3 and R4 and is input to the differential amplifier A2.
The liquid crystal drive voltages V 2 , r , V, ;.5 all depend on the liquid crystal drive voltage vl.

Further, the liquid crystal drive voltage vl changes in accordance with the reference voltage. Therefore, by varying the reference voltage using the variable resistor R1, all liquid crystal drive voltages V1, V2, v4, V
5 can be varied simultaneously and adjusted to the optimum value. That is, in the above first embodiment = 10 -, each liquid crystal drive voltage Vl, 2, V4, ■5
is initially set at the optimum bias ratio, and the variable resistor R
1, the bias ratio is variably adjusted at the same time so as to obtain the optimum potential while keeping it fixed.

[Second Embodiment of the Invention] Next, a second embodiment of the invention shown in FIG. 3 will be described. In this second embodiment, the DC power source E1 is connected to the resistors R1 and R2.
The reference voltage is fixed in advance to a constant reference voltage, and is supplied to the ten terminals of the differential amplifier At. In addition, the DC power source E2 is connected to the resistor R3.
, R4 and supplied to one terminal of the differential amplifier A3. In this case, R3 is a variable resistor so that the reference voltage input to the differential amplifier A3 can be varied.

The rest of the structure is the same as that of the first embodiment shown in FIG.

In this second embodiment, as shown in FIG. 4, the liquid crystal drive voltages Vl and V5 are fixed at optimal bias potentials,
Liquid crystal drive voltages V2 and V4 are set to appropriate values.

However, rVl - -V5 J, rV2 = -V4 J. Therefore, in this embodiment, the values of the liquid crystal drive voltages v2 and V3 are simultaneously varied by the variable resistor R3, so as to obtain the optimum bias ratio and potential.

[Third Embodiment of the Invention] Next, a third embodiment of the invention shown in FIG. 5 will be described. In this embodiment, in contrast to the first embodiment, a thermistor Rs is connected in parallel to the resistor R1, and a Zener diode D for protecting the liquid crystal driver is connected in parallel to the resistor R2, and temperature compensation is performed by the thermistor Rs. This is how it was done.

In this case, the anode side of the diode D is grounded.

In the above configuration, the number of scanning electrodes of the liquid crystal display panel is N
As a book, the effective values Von and VOf(' of the applied voltages to the display pixels and non-display pixels of the liquid crystal display panel are as follows.

here, Then, Vl-ABE and V2-CVI.

Therefore, the above Von and Voff are as follows.

From the above formula, the bias ratio (of display pixels and non-display pixels) Von/
The calculation of Voff is as follows.

By the way, when the thermistor Rs changes depending on the temperature,
The value of A above changes. As a result, as can be seen from equations (1) and (2) above, the effective values of the voltages applied to display pixels and non-display pixels change simultaneously, and temperature compensation of the liquid crystal is performed. At this time, from the above equation (3), the bias ratio V on/V o
The value of ff remains unchanged.

[Fourth Embodiment of the Invention] Next, a fourth embodiment of the invention shown in FIG. 6 will be described. This embodiment differs from the third embodiment in that the thermistor Rs and Zener diode D connected to the input terminal of the differential amplifier A1 are omitted, and the output voltage of the DC power supply E is divided by resistors R3 and R4. The reference voltage is supplied to the differential amplifier 8 as a reference voltage. A thermistor Rs is connected in parallel to the resistor R3 to compensate for the temperature of the circuit.

The other circuits are configured similarly to the third circuit.

In the above configuration, the effective values B on and V of'f of the voltages applied to the display pixels and non-display pixels of the liquid crystal display panel are expressed by the same formulas as in the third embodiment.

Here, if we set Vl-A, BE, and V2-clE. Therefore, the above V o n s V o f'f' becomes as follows.

From the above formula, the bias ratio of display pixel and non-display pixel Von/V
Off' is calculated as follows.

In this embodiment, when the thermistor Rs changes depending on the temperature, the value of C1 changes.

When the value of C1 changes, as can be seen from equations (4) and (5) above, the effective values of the voltages applied to the display pixels and non-display pixels change simultaneously, and the temperature compensation of the liquid crystal changes as in the third embodiment. It is done. At this time, from the above equation (6), the bias ratio V
The value of on/VolT also changes at the same time.

Since the liquid crystal driving voltage v1 is expressed by Vl = A, E, the value of Vl remains unchanged regardless of changes in C1. Further, the liquid crystal drive voltage v2 is expressed as V2-C,E, and the value changes as C1 changes, but since it is generally Vl)V2, the value of v2 is set to a very small value.

Therefore, the voltage does not increase to the extent that it destroys the liquid crystal driver, so the protective Zener diode can be omitted in this embodiment.

Therefore, in the third and fourth embodiments, when the effective values of the applied voltages of the display pixels and non-display pixels of the liquid crystal display panel are equal, the equations (1)-(4), (2 )
-(5). Solving this equation gives A,
The relational expression C1-A2BC holds true. Therefore, when the above relational expression holds true, the third embodiment and the fourth embodiment become equivalently equivalent circuits.

[Effects of the Invention] As described in detail above, according to the present invention, one or two reference voltages are generated by dividing the DC voltage Δ); Since a plurality of liquid crystal drive voltages are generated by amplification using a circuit combining inverting amplifiers, the bias ratio and voltage level can be easily adjusted by reducing the number of adjustment points.

Further, according to the present invention, a thermistor is connected in parallel to the voltage dividing resistor of the voltage dividing circuit to perform temperature compensation, so that adjustment of the liquid crystal drive voltage is easy and temperature compensation can be performed reliably. It is.

[Brief explanation of the drawing]

FIG. 1 is a circuit configuration diagram showing the first embodiment of the present invention, FIG. 2 is a diagram for explaining the adjustment operation of the liquid crystal drive voltage in the same embodiment, and FIG. 3 is a diagram showing the second embodiment of the present invention. FIG. 4 is a diagram for explaining the adjustment operation of the liquid crystal drive voltage in the same embodiment, FIG. 5 is a circuit diagram showing the third embodiment of the present invention, and FIG. FIG. 7 is a circuit diagram showing the fourth embodiment, FIG. 7 is a diagram showing the configuration of a conventional liquid crystal drive voltage generation circuit, and FIG. 8 is a diagram for explaining the adjustment operation of the liquid crystal drive voltage in FIG. 7. E, El, E2...DC power supply, A1-A4...Differential amplifier, Rs...Thermistor, D...Zener diode. Applicant's Representative Patent Attorney Takehiko Suzue Figure 1 Initial Settings Elm Optimal Bias Figure 2 Initial Settings ◇ Optimal Bias Figure 4 Figure 5

Claims (4)

[Claims] (1) A DC power supply, a voltage divider circuit that divides the output voltage of this DC power supply to generate a reference voltage, a variable resistor installed in this voltage divider circuit to adjust the level of the reference voltage, and this voltage divider. a non-inverting amplifier that amplifies a reference voltage output from the circuit and outputs a first liquid crystal drive voltage; an inverting amplifier that inverts and amplifies the first liquid crystal drive voltage and outputs a second liquid crystal drive voltage; a non-inverting amplifier that amplifies the first liquid crystal drive voltage and outputs a third liquid crystal drive voltage; and an inverting amplifier that inverts and amplifies the third liquid crystal drive voltage and outputs a fourth liquid crystal drive voltage. A liquid crystal drive voltage generation circuit characterized by comprising: (2) A first DC power supply, a first voltage divider circuit that divides the output voltage of the DC power supply to generate a first reference voltage, and a reference voltage output from the first voltage divider circuit. a non-inverting amplifier that amplifies and outputs a first liquid crystal driving voltage;
an inverting amplifier that inverts and amplifies a liquid crystal drive voltage to output a second liquid crystal drive voltage; a second DC power supply; and a second reference voltage that is generated by dividing the output voltage of the second DC power supply. a second voltage dividing circuit; a variable resistor provided in the second voltage dividing circuit to adjust the level of the second reference voltage; and a second reference voltage output from the second voltage dividing circuit. and an inverting amplifier that inverts and amplifies the third liquid crystal drive voltage and outputs a fourth liquid crystal drive voltage. LCD drive voltage generation circuit. (3) A DC power supply, a voltage divider circuit that divides the output voltage of the DC power supply using a resistor and outputs a reference voltage, a temperature compensation thermistor connected in parallel to the voltage divider resistor of this voltage divider circuit, and a reference voltage. a Zener diode for suppressing the voltage, a non-inverting amplifier for amplifying the reference voltage output from the voltage divider circuit to output a first liquid crystal drive voltage, and a non-inverting amplifier for inverting and amplifying the first liquid crystal drive voltage to output a second liquid crystal drive voltage. an inverting amplifier that outputs a liquid crystal driving voltage, and a third liquid crystal driving voltage that amplifies the first liquid crystal driving voltage.
A liquid crystal drive voltage generation circuit comprising: a non-inverting amplifier that outputs a liquid crystal drive voltage; and an inverting amplifier that inverts and amplifies the third liquid crystal drive voltage and outputs a fourth liquid crystal drive voltage. (4) a DC power supply, a first voltage divider circuit that divides the output voltage of the DC power supply to generate a first reference voltage;
a non-inverting amplifier that amplifies the reference voltage output from the voltage divider circuit to generate a first liquid crystal driving voltage; and an inverting amplifier that inverts and amplifies the first liquid crystal driving voltage to generate a second liquid crystal driving voltage. an amplifier, a second voltage divider circuit that divides the output voltage of the DC power supply using a resistor to generate a second reference voltage lower than the first reference voltage, and a voltage divider resistor of the second voltage divider circuit. a temperature-compensating thermistor connected in parallel to the second voltage dividing circuit; a non-inverting amplifier that amplifies the second reference voltage output from the second voltage dividing circuit to output a third liquid crystal driving voltage; 1. A liquid crystal drive voltage generation circuit comprising: an inverting amplifier that inverts and amplifies a liquid crystal drive voltage to generate a fourth liquid crystal drive voltage.