DE69023203T2 - Driver circuit for a scoreboard. - Google Patents

Description

BACKGROUND OF THE INVENTION

The invention generally relates to a reference potential side driver circuit for driving a high capacitive load, such as a reference potential side electrode or the like of a liquid crystal panel.

A conventional reference side drive circuit of this type incorporated in a conventional liquid crystal display device is shown in Fig. 6. A bias voltage is supplied from a variable resistor (2) to a buffer amplifier (1) to which a reference side amplitude signal (frame pulse) (FP) is input. The amplitude of the reference side amplitude signal is adjusted by adjusting the bias voltage on the variable resistor (2). The DC bias voltage at the output of the buffer amplifier (1) is removed by a capacitor (C1), and the signal output from the capacitor (C1) is adjusted to a new bias voltage value by a variable resistor (1). The output signal of the circuit is supplied to the reference side electrode of a liquid crystal panel.

In this conventional embodiment, in order to obtain an amplitude signal to which a reference potential side bias is added, the DC component must be removed from the output signal of the buffer amplifier (1) by the capacitor (C1). This requires a large capacitance (C1). Also, the reference potential side bias depends on the supply voltages Vcc, -Vee, as they are applied to the variable resistor (3), and the reference potential side bias voltage also changes with a change in the supply voltages, thereby exerting undesirable influences on the liquid crystal panel.

Fig. 6 illustrates a conventional method in which the DC component of the reference side output signal is removed by a capacitor (C1) after amplification of the frame pulse and then a bias voltage is added by the variable resistor. The amplitude of the reference side output signal sometimes fluctuates up to 8 Vpp at the maximum. Also, sometimes the supply voltage -Vee supplied to the variable resistor (3) cannot be adjusted to the voltage of the power source of the panel depending on the bias voltage to be applied. Therefore, it has been necessary to take the voltage -Vee from a much lower voltage (-21 V) since the voltage changes independently of the change in the supply voltage of the panel, and the DC bias voltage can be additionally applied to the panel when the voltage is not stable. If the voltage for setting the bias voltage is taken from the same power line as the power supply of the panel, the bias voltage set by the variable resistor 3 fluctuates in the same direction as the fluctuation of the power supply voltage, with the disadvantage that it is difficult to apply a direct current to the panel. Also, according to the specification of the panel, both the fluctuation of the central voltage of the video signal as applied to the source driver and the fluctuation of the central voltage of the reference-side output signal itself during operation of the display, voltage fluctuations, etc. must be adjusted. In the case of the video signal, coupling is already used and this is stable, while in the case of the reference-side Output signal specifications may not necessarily be met for the reasons described above.

EP-A-0 199 361 discloses a drive circuit for an LCD display in which the DC bias level of a signal to a reference potential electrode can be changed by varying the high and low supply voltages applied to a pair of drive transistors.

SUMMARY OF THE INVENTION

Accordingly, the invention has been developed with a view to improving the above-described disadvantages and aims to provide a reference-side driver circuit capable of supplying a reference-side output signal provided with a stable bias voltage with a small fluctuation in the reference-side bias voltage without requiring a large capacitor for removing the DC component of an input signal.

A driver circuit for controlling a liquid crystal display according to supplied control signals is created, with

- an output circuit which supplies the liquid crystal display with drive signals, a supply circuit which supplies the output circuit with the provided drive signals, and an adjustment circuit for specifying a desired DC bias level for the drive signals;

characterized by a sampling circuit which checks the DC voltage level of the signal output of the output circuit, and a control device for the feed circuit, to set the desired level of DC bias voltage depending on the output of the setting circuit and the sampling circuit.

According to this structure, since the reference-side bias voltage is given from the bias voltage adjusting means to the output circuit, when the reference-side bias voltage fluctuates, the fluctuation is compensated by the control means so that it is maintained normally.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other objects and features of the invention will become apparent from the following description taken in conjunction with the preferred embodiment thereof with reference to the accompanying drawings in which:

Fig. 1 is a block diagram showing a liquid crystal display device incorporating a reference potential side driving circuit according to the present invention;

Fig. 2 is a block diagram schematically showing the structure of a reference potential side driving circuit according to an embodiment of the invention;

Fig. 3 is a circuit diagram showing a detailed circuit to the block diagram of Fig. 2;

Fig. 4 is a waveform diagram for the respective signals at each indicated point in Fig. 1 and Fig. 3;

Fig. 5 is a circuit diagram showing a modified embodiment of the circuit of Fig. 3; and

Fig. 6 is a circuit diagram showing a conventional reference potential side driving circuit.

DETAILED DESCRIPTION OF THE INVENTION

Before proceeding with the description of the invention, it is pointed out that throughout the accompanying drawings, similar parts are designated by the same reference numerals.

Example:

Fig. 1 is a block diagram showing the structure of a complete liquid crystal display device in which a reference-side driving circuit is included. Fig. 2 is a block diagram of a reference-side driving circuit according to an embodiment of the invention. Fig. 3 is a circuit diagram showing the circuit structure of the respective blocks in Fig. 2. Fig. 4 is a waveform diagram of the signals at each indicated point in Fig. 1 and Fig. 3.

In the liquid crystal display panel of Fig. 1, an LCD panel 40 consisting of a TFT (thin film transistor) array is provided with a gate driver 40a, a source driver 40b, and a common side driver 39 for inputting a gate drive signal from a liquid crystal panel controller 38 to a gate driver 40a, inputting a source drive signal to the source driver 40b, and inputting a common side signal to the common side driver 39.

A video signal is input to a synchronizing signal separating circuit 31 and a Y/C separating circuit 33. The synchronizing signal input to the synchronizing signal separating circuit 31 The video signal separated synchronously by the separating circuit 31 is supplied to a liquid crystal panel controller 38 and a clamp pulse generator 32 having a sinusoidal waveform of 10 MHz or more as shown in Fig. 4(a). In the Y/C separating circuit 33, the video signal is separated into a luminance signal and an image signal and input to a video image signal processing circuit 34. From this video image signal processing circuit 34, primary color signals R, G, B are output and input to a brightness, contrast, gamma correction circuit 35. The clamp pulse of a clamp pulse generator 32 is input to the video image signal processing circuit 34 and the brightness, contrast, gamma correction circuit 35. The primary color signals R, G, B of the brightness, contrast, gamma correction circuit 35 are processed in an inverter circuit 36 and input as a video output signal from a driver circuit 37 to the source driver circuit 40b. The liquid crystal panel controller 38 receives as an input the synchronizing signal from the synchronizing signal separating circuit 31 and also receives a clock pulse ck as an input signal, and outputs the gate drive signal and the source drive signal as a control signal for the panel. At the same time, a horizontal period signal of 15 MHz of 0 to 5 V is output as a frame pulse (FP) synchronized with the signal or an inversion pulse to generate a reference side signal. The inversion pulse to be output from the liquid crystal panel controller 38 is input to an inverter 36 and a reference side driver 39. A horizontal period signal of 15 kHz with a DC level of 0 to 5 V as shown in Fig. 4(b) is input as a reference side amplitude signal (from a terminal 10 shown in Fig. 2) to a buffer amplifier 11 of the reference side driver 39. A control section (12) for controlling the bias amplitude is connected to the buffer amplifier (11). The control section (12) supplies a setting value prepared by an amplitude varying means (13) to the buffer amplifier (11), and also compares, by means of a comparator, a bias voltage set by a bias voltage setting means (14) with a DC level fed back from the output circuit to vary the bias voltage by comparison with the output signal and supply it to the buffer amplifier (11). To an operational amplifier (15) connected to the buffer amplifier, the output signal of the above-mentioned buffer amplifier (11) is input at the (+) input terminal as a pulse signal having a DC level of -1 V to -7 V with a central bias voltage of -4 V, as shown in Fig. 4(c). The output of the operational amplifier (15) is given to transistors (Q1), (Q2) to drive the high capacitive load, performing voltage feedback from the output point (a) to the (-) input terminal of the comparator 15. Thus, the operational amplifier (15) and the buffer amplifiers (Q1), (Q2) constitute a voltage follower 18. The voltage follower constitutes an output circuit (18) with the output point (a) connected to the reference potential side electrode of the liquid crystal panel, and the output is supplied as a pulse signal having a DC level of -1 V to -7 V, with -4 V being the center bias, as shown in Fig. 4(d). It is also connected to a low-pass filter (16) consisting of a resistor (R1) or a capacitor (C1). The output signal of the low-pass filter is supplied to the above-mentioned blocking section (12) via a feedback circuit (17) as a signal of -4 V as shown in Fig. 4(e). The feedback circuit (17) consists of an operational amplifier, wherein the output signal of the above-mentioned low-pass filter (16) is supplied to the positive input terminal and the voltage Vcc/2 is supplied to the negative input terminal. The output of the feedback circuit (17) is supplied as a signal of -4 V as shown in Fig. 4(f) to one input terminal of the first and second comparators (20, 21, in Fig. 3) which form a portion of the control section (12). The DC voltage set by the bias setting means (14) is supplied to the other input terminal of the comparator 20. The output of the comparator 21 controls the bias voltage to be supplied to the buffer amplifier (11) so that the DC voltage to be supplied via the feedback circuit (17) from the above-mentioned low-pass filter (16) coincides with the DC voltage from the above-mentioned DC voltage adjusting circuit (14) as a pulse signal varied by the means (13) and (14) in both DC level and amplitude as shown in Fig. 4(g).

Fig. 3 shows a detailed circuit to the block diagram shown in Fig. 2. The buffer amplifier 11 consists of an amplifier 19 and resistors R1, R2, R3, R4. The voltage follower 18 consists of the operational amplifier 15 and a pair of transistors Q1, Q2 for buffer purposes. The feedback circuit 17 consists of an amplifier 22 and a resistor R6.

The low-pass filter circuit 16 consists of a resistor R1 and a capacitor C1, the direct current component of which is input to the amplifier 22 of the feedback circuit 17. The output signal of the amplifier 22 is supplied to the first comparator 20 and the second comparator 21 of the control section 12. The control section 12 consists of the first comparator 20, the second comparator 21, resistors R7, R8, R9, R10 and a capacitor C2. The amplitude changing device 813) which is connected to the first comparator 21 is used to adjust the amplitude of the output signal of the control section (12). The bias voltage adjusting device 14 connected to the second comparator 20 is used to adjust the central bias voltage of the output signal from the control section (12).

The inversion pulse input from the terminal (10) is amplified (or reduced) by the control signal from the control section (12) through the circuit 11, and at the same time, the bias voltage is also adjusted. The bias voltage control signal to be produced by the amplifier circuit (12) is formed by comparison by the feedback circuit (17) between a reference level set by the bias voltage adjuster (14) and the level of a signal from the low-pass filter (16). The gain of the circuit (11) is adjusted so that the output signal of the voltage follower (18) is normally constant. A capacitor C3 is provided together with a resistor R6 for smoothing.

The inversion pulse input to the reference side driver 39 is designed to be added in the liquid crystal panel LCD, the amplitude is stabilized by the circuit of Fig. 3 and the bias voltage is adjusted.

The reference potential side driver circuit according to the invention consists of a block circuit as shown in Fig. 2, and it can be realized as shown in the circuit diagram of Fig. 5, which is a modified embodiment, in addition to the circuit of Fig. 3. In the circuit shown in Fig. 5, the inversion pulse supplied to the input terminal (51) is input to the operational amplifier (52). The amplitude of the input inversion pulse is determined by the variable feedback resistor (53). The output of the amplifier (52) is input to the voltage follower (54), and it is output as a reference side output. Also, the reference side bias voltage is taken out by the low-pass filter consisting of the resistor R17 and the capacitor C12 and input to the comparator (56). In the comparator (56), the level set by the comparator (57) and the variable resistor (58) is compared with the output level of the above-mentioned low-pass filter, and the output of the comparator is input to the voltage follower (55) through the low-pass filter consisting of the resistor R18 and the capacitor C13. The output signal is fed to the amplifier (52) so that the output of the low-pass filter consisting of the resistor R17 and the capacitor C12 normally assumes the level set by the variable resistor (58) by means of the direct current as shown in Fig. 4(g). The capacitor C11 in Fig. 5 is provided to remove the high frequency component (especially at higher frequency). The capacitor C13 smoothes the output of the comparator (56) which drops to the reference voltage (the output of the comparator 57). The capacitor C14 provides protection against noise signals.

In Fig. 5, the common side output signal is smoothed by the resistor R17 and the capacitor C12 and input to the comparator (56). Also, the bias value VR of the potentiometer (58) is established using both Vcc and Vee from the same supply line from which the panel receives its supply voltage. The bias voltage to be set by the potentiometer (58) sets the bias of the common side output signal and it also becomes the reference voltage for the DC feedback so that it can withstand even a fluctuation the supply voltage. When the supply voltage has changed, the variation of the voltage to be applied to the panel becomes smaller because of the shift corresponding to the variation of the reference voltage. Since the circuits in this structure are all directly connected, the capacitor for cutting off DC current is not required. The modified example of Fig. 5 gives the same effect as that of Fig. 3, with stability in that the feedback resistor (53) is changed for amplitude adjustment.

As is clear from the above description, the reference side driving circuit of the present invention has a simple structure comprising a voltage follower, a low-pass filter, feedback and control circuits. Variation of the DC component, which adversely affects signal processing in this type of circuit, is prevented, improving reliability. Also, no DC separation is required at the input end of the output circuit for establishing a reference side bias, so that a large-capacity capacitor for separating the DC is unnecessary.

Claims (7)

1. Driver circuit for a liquid crystal display (40) with an output circuit (18;54) which supplies the liquid crystal display (40) with driver signals, a supply circuit (11;amp,R₁₅,53); which supplies the output circuit (18;54) with the provided driver signals, and an adjustment circuit (14;58) for specifying a desired DC bias level for the driver signals, characterized by a sampling circuit (R₁,C₁;R₅,C₁;R₁₇,C₁₇) which checks the DC level of the signal output of the output circuit (18;54), and a control device (12,13,14,17;56,R₁₈,55,C₁₃,R₁₇,57,C₁₄,58) for the supply circuit (11;amp,R₁₅,53) to set the desired level of the DC bias depending on the output of the setting circuit (14;58) and the sampling circuit R₁,C₁;R₅,C₁;R₁₇,C₁₇). 2. Driver circuit according to claim 1, wherein the sampling circuit (R₁,C₁;R₅,C₁; R₁₇,C₁₂) is a low-pass filter. 3. Driver circuit according to claim 1 or claim 2, in which the supply circuit (11;amp,R₁₅,53) comprises an operational amplifier (19;52) which receives the provided driver signals at a first input connection point and a control signal from the control device (12,13,14, 17;56,R₁₈,55,C₁₃, R₁₇,57,C₁₄,58) at a second connection point. 4. Driver circuit according to one of the preceding claims, in which the output circuit (18; 54) is a voltage follower with an operational amplifier (15) and a buffer amplifier (Q₁, Q₂; Q₁₁, Q₁₂), the output of the operational amplifier (15) being coupled to the sampling circuit (R₁, C₁; R₅, C₁; R₁₇, C₁₂). 5. Driver circuit according to one of the preceding claims, in which the control device includes an amplitude checker (13) for adjusting the amplitude of the control signal with which the supply circuit (11) is supplied. 6. Driver circuit according to one of claims 1 to 4, wherein the supply circuit (11;amp,R₁₅,53) comprises means (53) which varies the amplitude of the output of the supply circuit (11;amp,R₁₅,53). 7. Driver circuit according to one of the preceding claims, in which the control device includes a comparator (22; 56) which compares the output of the sampling circuit (R₁, C₁; R₅, C₁; R₁₇, C₁₇) with the output of the setting circuit (14; 58) and changes the control signals provided to the supply circuit (11; amp, R₁₅, 53) depending thereon.