JPH0685571B2 - liquid crystal television - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of application] The present invention relates to brightness adjustment of a liquid crystal television.

[Conventional technology]

The relationship between the input dynamic range (range with contrast) and the video signal amplitude of a conventional LCD TV is as follows.
It was generally about 1.5 times.

(1) The contrast ratio of the liquid crystal display is smaller than that of a cathode ray tube, and with an average video signal with little difference in brightness,
Since the sense of contrast is insufficient, it is necessary to increase the amplitude of the video signal to enhance the contrast.

(2) It is safer to increase the amplitude of the video signal due to variations in the input dynamic range of the liquid crystal display and changes in the input dynamic range due to temperature changes.

[Problems to be solved by the invention]

As described above, the conventional liquid crystal television has a larger video signal amplitude than the input dynamic range of the liquid crystal display,
There is a problem in that a bright video signal is dark when the brightness is adjusted and a dark video signal is received when the dark video signal is bright and the brightness must be manually adjusted frequently.

Further, since it is necessary to adjust frequently, luminance adjustment, which is an auxiliary adjustment means in addition to color adjustment and hue adjustment in a CRT television, is the main adjustment means in a liquid crystal television.

The present invention solves such a problem, and the purpose thereof is to ensure sufficient contrast, and to be able to always listen with optimum brightness regardless of the change in the brightness of the video signal. To provide high-quality LCD TVs.

[Means for solving problems]

According to the present invention, in a liquid crystal television having a liquid crystal display, an amplifier unit that outputs a voltage obtained by inverting and amplifying an average DC voltage of a video signal, and a brightness control amount is determined based on the output voltage from the amplifier unit. And a brightness control amount determination unit, the maximum voltage amplitude of the video signal to be displayed on the liquid crystal display is made larger than the width of the voltage range in which the liquid crystal display can add contrast, and the voltage of the video signal is increased. A bias voltage that changes based on the brightness control amount is applied to the bias voltage of the video signal with respect to the voltage range of the liquid crystal display when the average DC voltage is relatively high. When the voltage is relatively low and the DC voltage is relatively low, the voltage of the video signal is changed to be relatively high with respect to the voltage range of the liquid crystal display. And

〔Example〕

 Hereinafter, the present invention will be described based on examples.

FIG. 1 is a diagram showing an embodiment of the present invention. In FIG. 1, 1 is an IF input, 2 is a video IF (video signal detection) IC, 3
Is a brightness change detection unit, 4 is a polarity inversion and amplification unit, 5 is a control amount determination unit, 6 is a response speed determination unit, 7 is a video chroma IC,
Reference numeral 8 is an RGB output to the liquid crystal display. The change in brightness of the video signal received by the liquid crystal television is detected based on the video detection output of the video IFIC2. As shown in FIG. 2, the video detection output output from the video IFIC 2 has different average DC potentials when a bright video signal is received and when a dark video signal is received. In FIG. 2, 1 is an example of an output waveform from the video IFIC2 when a staircase wave of a video signal is input, 2 is an example of an output waveform when a bright video signal is input,
3 is an example of an output waveform when a dark video signal is input. In each example, the average DC potential is different from each other. In the example of FIG. 2, the output amplitude of the video signal is about 1V, which is 2-3V, and the average DC potential of the video signal depends on the modulation content of the video signal.
Change from 2.4 to 3.0V.

A signal extracted from the video detection output from the video IFIC2 by the brightness change detection unit 3 having a sufficiently high impedance with respect to the signal system is applied to the base of the transistor Q1 of the polarity inversion / amplification unit 4 and the polarity inversion is applied to its collector. Obtain the amplified output signal. The inverted and amplified output signal changes between 7.4 and 5.8 V depending on the modulation content of the video signal, as if the change of the video signal was inverted.

Brightness adjustment is included in the function of the video chroma IC, and consists of brightness adjustment range limiting resistors R6 and R7 inserted on the power supply side and ground side, and a brightness adjustment circuit connected in series with variable resistance VRI. . By operating the brightness adjustment terminal of the video chroma IC, the resistance node of the variable resistor VRI is changed, and a voltage of 6.2 to 7.0 V is taken out as the DC voltage. The brightness is controlled so that the maximum brightness is dark at 6.2V and the maximum brightness is bright at 7.0V.

The control amount determining unit 5 forms the brightness control voltage by superposing the output voltage from the brightness adjusting circuit and the collector output voltage of the transistor Q1 with the resistors R5 and R4, and determines the brightness control amount. When the resistance ratio R4 / R5 is decreased, the brightness control amount decreases, and the saturation of brightness occurs on the white side when receiving a bright video signal and the black side when receiving a dark video signal, but this is natural. On the other hand, when R4 / R5 is increased, the brightness control amount is increased, and the saturation of the brightness is less likely to occur, but there is an unnatural effect that the scene is in the evening. The brightness control voltage fluctuates based on the output voltage of the inverting and amplifying unit 4 with reference to the voltage based on the output voltage from the brightness adjustment circuit, and the degree of this fluctuation is determined by the resistance ratio of R4 / R5.

In this embodiment, as shown in FIG. 3, the video signal amplitude is set to 3.0 V with respect to the input dynamic range (voltage range to which contrast can be added) of 2.0 V of the liquid crystal display, ± 0.4 V. R4 / R5 is set to 2.2 to suppress saturation on the white side and black side within the range where control is performed and naturalness is not impaired. Therefore, when the output from the brightness adjusting circuit is 6.2V, the control voltage changes from 1.95 to 2.45V, and when the output from the brightness adjusting circuit is 7.0V, the control voltage changes from 2.5 to 3.0V.

In FIG. 3, 1 is an example of an input waveform to the liquid crystal display when a stepwise wave of a video signal is input, 2 is an example of an input waveform to the liquid crystal display when a bright video signal is input, and 3 is a dark video signal input 2 is an example of an input waveform to the liquid crystal display body of FIG. The input dynamic range 4 of the liquid crystal display is fixed at 2.0V from 2 to 4V,
The video signal is supplied with a bias voltage obtained based on the voltage from the resistance VRI of the brightness adjusting circuit and the brightness control voltage that fluctuates based on the average inversion / amplification voltage of the video signal. Reference numeral 5 is a control range (± 0.4 V) controlled by the bias voltage. The reference value for adjusting the control range 5 is
It is determined by the resistance VRI of the brightness adjustment circuit in Fig. 1. Also,
Due to the adjustment within the control range 5, when the original video signal changes in the dark state, it is lower than the center of the input dynamic range, and when the original video signal changes in the bright state, it changes from the center of the input dynamic range. Change on the high side.

The response speed determination unit 6 of the circuit determines the response speed of the automatic adjustment of the luminance to the video signal based on the time constant of the circuit based on the capacitance of C1. If the response speed is too fast, the brightness changes due to the screen portion, which is unnatural, and if it is too slow, it becomes impossible to follow the changes in the video signal, and about 1/60 second is a good result. Become.

〔The invention's effect〕

As described above, according to the present invention, by automatically controlling the brightness adjustment in response to the change in the brightness of the video signal, a video display device having a contrast ratio lower than that of a cathode ray tube such as a liquid crystal display is provided. In the television used, the amplitude of the video signal to be input is made larger than the input dynamic range of the liquid crystal display to enhance the contrast, and there is an effect that there is no need to adjust the brightness for a change in the brightness of the video signal. Since the fine adjustment of the video signal for the input dynamic range of the liquid crystal display is given as the bias voltage,
When the original video signal changes in a bright state, it will be displayed as such, and when it changes in a dark state, it will be displayed as such. Video signals can be displayed on the display.

[Brief description of drawings]

FIG. 1 is a diagram showing an embodiment of a liquid crystal television of the present invention. (1) ... IF input (2) ... Video IFIC (3) ... Luminance change detection unit (4) ... Polarity inversion and amplification unit (5) ... Control amount determination unit (6) ... Response speed determination unit (7) ... Video Chroma IC (8) ... RGB output FIG. 2 is a diagram showing a signal waveform of the video detection output of the video IFIC. (1) ... Output waveform when staircase is input (2) ... Output waveform when bright video signal is input (3) ... Output waveform when dark video signal is input (4) ... Output amplitude, about 1V Figure 3 shows liquid crystal display It is a figure which shows the input dynamic range of a body, the video signal amplitude, and the mode of control. (1) ... Input waveform to the liquid crystal display when a staircase wave is input (2) ... Input waveform to the liquid crystal display when a bright video signal is input (3) ... Input waveform to the liquid crystal display when a dark video signal is input (4) ... Input dynamic range of liquid crystal display (5) ... Control range according to embodiment of the present invention

Claims (2)

[Claims] 1. In a liquid crystal television having a liquid crystal display, an amplification section that outputs a voltage obtained by inverting and amplifying an average DC voltage of a video signal, and a brightness control amount is determined based on the output voltage from the amplification section. And a brightness control amount determining unit that makes the maximum voltage amplitude of the video signal to be displayed on the liquid crystal display larger than the width of the voltage range in which the liquid crystal display can add contrast, A bias voltage that changes based on the brightness control amount is applied to the voltage, and the bias voltage is the video signal with respect to the voltage range of the liquid crystal display when the average DC voltage is relatively high. When the DC voltage is relatively low, the voltage of the video signal is changed to be relatively high with respect to the voltage range of the liquid crystal display. Characterizing liquid crystal television. 2. A response speed determining unit for delaying a change in the brightness control amount with respect to a change in the video signal by substantially one vertical scanning period of the video signal, according to claim 1. liquid crystal television.