JPS6358512B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to a contrast adjustment circuit for an image display device that samples and displays a video signal, typified by a liquid crystal television.

[Prior art and its problems] In the case of conventional CRT television receivers, contrast adjustment is performed by changing the amplification degree of the video signal to adjust the peak to
This was done by adjusting the width of the peak.

On the other hand, since liquid crystal televisions have lower contrast and narrower gradation width than cathode ray tubes, there is a concept of changing the reference voltage for A-D conversion depending on the level of the video signal. In other words, make effective use of the gradation width of the liquid crystal by increasing the reference voltage for A-D conversion when the image is entirely whitish, and lowering the reference voltage when the image is entirely black. This is the idea.

In such LCD TVs, when the video signal has an average amplitude, it is possible to obtain sufficient contrast, but when the video signal has an extremely large amplitude, the image appears somewhat distorted. When a video signal has an extremely small amplitude, there is a problem in that the image has low contrast.

[Object of the invention] This invention was made in view of the above circumstances,
An object of the present invention is to provide a contrast adjustment circuit for an image display device that can adjust the contrast according to the characteristics of the video signal in an image display device that performs AD conversion on a video signal and displays the result.

[Summary of the Invention] In order to achieve the above object, the present invention provides an upper limit reference potential for an A-D converter that is generated based on two potentials that are symmetrical with respect to a center potential for A-D converting a video signal. By making it possible to change the voltage width between the lower limit reference potential and the lower limit reference potential, appropriate contrast can be obtained both when the amplitude of the video signal is large and when the amplitude is small.

[Embodiment of the Invention] An embodiment of the invention will be described below with reference to the drawings. FIG. 1 shows the configuration of the main parts of a liquid crystal television receiver. In the figure, reference numeral 1 denotes a video amplification circuit which amplifies a signal from a video detection circuit (not shown) and outputs it to a synchronous separation circuit 2 and an AD converter 3. Further, a part of the output signal of the video amplification circuit 1 is sent to an audio amplification circuit (not shown). The synchronization separation circuit 2 separates horizontal and vertical synchronization signals from the input video signal and outputs them to the control circuit 4. This control circuit 4 provides a drive timing signal to a first drive circuit 6 via a shift register 5, and also provides a timing signal to a second drive circuit 7. The first drive circuit 6 scans the liquid crystal display panel 8 in the vertical direction, and the second drive circuit 6 scans the liquid crystal display panel 8 in the vertical direction.
The drive circuit 7 scans the liquid crystal display panel 8 in the horizontal direction. Further, the control circuit 4 generates a chip enable signal for selecting a video signal every other horizontal scan, and supplies it to the A/D converter 3. This A-D converter 3 includes a reference potential generation circuit 11,
It is mainly composed of comparators 12 ₁ to 12 _o , a decoder 13, and a bias circuit 14. As will be described in detail later, the reference potential generation circuit 11 generates a low level reference potential V _L and a high level reference potential V _H in accordance with the white level voltage and black level voltage of the video signal. The potentials V _L and V _H are input to the reference terminals of the comparators 12 ₁ to 12 _o directly or after being divided by the resistors R1 to Rm. The output signal of the video amplification circuit 1 is applied to the comparison terminals of the comparators 12 ₁ to 12 _o . On the other hand, the bias circuit 14 receives a chip enable signal.
Operates in synchronization with CE, comparators 12 ₁ to 12
Give a bias to _o . Comparator 12 ₁ to 12
_o operates while bias is applied from the bias circuit 14 and inputs its output signal to the decoder 13. This decoder 13 decodes the input signal into a 4-bit digital signal, for example, and converts the A-D
It is sent to the shift register 9 as the output of the conversion device 3. For example, if the liquid crystal display panel 8 is a 120×160 dot double matrix, the shift register 9 is configured to have 4 bits×320 stages. The data input to the shift register 9 is sent to the second drive circuit 7 via the buffer 10. The second drive circuit 7 performs brightness modulation on the output of the buffer 10 based on the brightness pulse from the control circuit 4, and applies a driving bias to the liquid crystal display panel 8.

Next, details of the reference potential generation circuit 11 will be explained with reference to FIG. The video signal sent from the video amplification circuit 1 is passed through the integration circuit 21 to the OP
It is input to the + input terminal of the amplifier 22. This OP
The amplifier 22 is used as a buffer for a voltage follower, and its output is input to its own negative input terminal, and also to the negative input terminal of an OP amplifier 24 via a resistor 23. A DC voltage of 1/2Vcc is applied to the +input terminal of this OP amplifier 24. The output of the OP amplifier 24 is inputted to its -input terminal via a resistor 25. The OP amplifier 24 is used as a DC inverting amplifier, and its output is input to the - input terminal of the OP amplifier 27 via a resistor 26, and also to the - input terminal of an OP amplifier 29 via a resistor 28. be done. In addition, the above OP amplifier 27,
A voltage of 1/2Vcc is applied to the + input terminal of 29. Furthermore, the voltage of Vcc is divided by a series circuit of a resistor 30, a variable resistor 31 for contrast adjustment, and a resistor 32, and the divided voltage between the resistor 30 and the variable resistor 31 is applied to the negative input terminal of the OP amplifier 29. The divided voltage between the variable resistor 31 and the resistor 32 is supplied to the - input terminal of the OP amplifier 27.
Further, the outputs of the OP amplifiers 27 and 29 are inputted to their own - input terminals via resistors 33 and 34, respectively. Then, the output of the OP amplifier 27 is set as the reference potential _VH , and the output of the OP amplifier 29 is set as the reference potential _VL.
is extracted as

Next, the operation of the above embodiment will be explained with reference to the signal waveforms of each part shown in FIG. The video amplification circuit 1 outputs a video signal a as shown in FIG. The video signal a is first integrated by an integrating circuit 21, and then amplified by an OP amplifier 22 to become a signal b as shown in FIG. 3b. This signal b is the video signal a
It changes according to the change in the average value of . The signal b is then inverted by the OP amplifier 24, resulting in a signal waveform shown in FIG. 3c. That is, since 1/2Vcc is given as the reference voltage of the OP amplifier 24, the output signal c of the OP amplifier 24 is c=(1/2Vcc-b)+1/2Vcc=Vcc-b. The output c of the OP amplifier 24 is inverted and amplified by the OP amplifier 27 to become a signal shown in FIG. 3e, that is, a reference voltage _VH . At this time, OP amplifier 2
The voltage of 1/2Vcc is input to the + terminal of 7, and the divided voltage d between the variable resistor 31 and the resistor 32 is input to the - terminal.
is given, the output e of the OP amplifier 27 is
is, e=V _H = (1/2Vcc-c) + (1/2Vcc-d) +1/2Vcc=3/2Vcc-c-d = 3/2Vcc-(Vcc-b)-d = 1/2Vcc+b- d. The divided voltage d is set to a value lower than 1/2Vcc, for example, as shown in FIG. 3d. Also,
The output of the OP amplifier 24 is inverted and amplified by the OP amplifier 29 to become a signal g shown in FIG. 3g, that is, a reference potential V _L. At this time, a voltage of 1/2Vcc is input to the + terminal of the OP amplifier 29, and a resistor 3 is input to one terminal.
Since the divided voltage between 0 and the variable resistor 31 is given, the output g of the OP amplifier 29 is: g=V _L = (1/2Vcc-c) + (1/2Vcc-f) +1/2Vcc =3/2Vcc-c-f =3/2Vcc-(Vcc-b)-f =1/2Vcc+b-f. The divided voltage f is set to a value higher than 1/2Vcc, for example, as shown in FIG. 3f.

Therefore, the divided voltages d, f in the above calculation formula
changes by adjusting the variable resistor 31, and the reference potentials _VH and _VL change accordingly. Further, the reference potentials V _H and V _L change according to the output b of the OP amplifier 22, that is, follow the average value of the video signal. Therefore, by adjusting the variable resistor 31, the width of the reference potentials V _H and V _L for A-D conversion changes around the average value of the video signal.

In the above calculation formula, if we set d=1/2Vcc-h f=1/2Vcc+h (h is an arbitrary value), it can be expressed as e=b+h g=b-h, so the reference potentials V _H , V _L does not depend on the power supply voltage Vcc. Therefore, the power supply voltage
Even if Vcc fluctuates, the level of A-D conversion,
In other words, the contrast is not affected.

In addition, the above h is 1/2Vcc in Figure 3 d and f.
In b, e, and g of the same figure, it means the difference between the level of b and the level of e, and the difference between the level of b and the level of g.

Therefore, the reference potentials V _H and V _L output from the reference potential generation circuit 11 can be directly or
The voltage is divided by 1~Rm and the comparator 12 ₁ ~
12 _o is input as a reference voltage. The comparators 12 ₁ to 12 _o take out the video signal output from the video amplifier circuit 1 according to the reference potentials V _H and V _L and convert it into 4-bit data via the decoder 13 . Therefore, A-D conversion is always performed around the average value of the video signal. That is, when the image is blackish, the average value of the video signal is low, so the reference potentials V _H , V _L are low, and when the image is whitish, the average value of the video signal is high, so the reference potentials V _H , V L are low. V _L
becomes high and A- for near the average value of the video signal.
A D conversion is performed. In this case, as described above, the widths of the reference potentials V _H and V _L change around the average value of the video signal by adjusting the variable resistor 31.
The A-D conversion output taken out from the decoder 13 changes depending on the width of the reference potentials V _H and V _L , and the contrast changes accordingly. That is, variable resistor 3
Contrast adjustment is performed by adjustment No. 1.

[Effects of the Invention] As described above, according to the present invention, contrast adjustment is performed by varying the voltage width between the upper limit reference potential and the lower limit reference potential of the A-D converter, so that the contrast of the video signal can be adjusted. It is possible to adjust the contrast to the optimum level whether the amplitude of the image is large overall or the amplitude is small overall. Furthermore, adjustment is extremely easy since it is only necessary to change the resistance value of one resistor.

Furthermore, since the upper limit reference potential and lower limit reference potential for A-D conversion do not depend on the power supply voltage, there is an effect that contrast is not affected even if the power supply voltage fluctuates.

[Brief explanation of drawings]

The drawings show one embodiment of the invention.
The figure is a circuit configuration diagram, and Figure 2 is A-D in Figure 1.
FIGS. 3a to 3g are circuit diagrams showing details of the reference potential generation circuit in the converter, and are operation signal waveform diagrams of each part in FIG. 2. 3... A-D converter, 11... Reference potential generation circuit, 12 ₁ to 12 _o ... Comparator, 13...
Decoder, 14...bias circuit, 21...integrator circuit, 22, 24, 27, 29...OP amplifier.

Claims (1)

[Claims] 1. A means for setting a center potential for A-D conversion of a video signal, and a means for dividing a power supply voltage by a resistor, and providing two potentials symmetrical to the center potential at both ends of a predetermined resistor. means for generating an upper limit reference potential and a lower limit reference potential for A-D conversion based on the two symmetrical potentials; 1. A contrast adjustment circuit for an image display device, comprising means for adjusting contrast by varying the voltage width of two potentials.