JPH0636586B2 - Television receiver - Google Patents

Description

The present invention relates to a television receiver suitable for use in, for example, a color video projector or the like.

[Outline of Invention]

According to the present invention, luminance is adjusted by using a reference pulse inserted in a predetermined portion of a video signal, and a polygonal line characteristic of a gamma correction circuit inserted in a video signal system is changed according to the level of the reference pulse. By doing so, the white balance is adjusted in all gradations.

[Conventional technology]

Conventionally, various circuits have been proposed as a circuit for adjusting the contrast and the brightness in a television receiver, but the applicant of the present invention has disclosed that the contrast and the brightness can be adjusted independently in Japanese Patent Application No. 59-128114. I proposed a circuit that does. FIG. 4 shows an example.

That is, in FIG. 4, (1) indicates a video signal input terminal, and the video signal supplied to the video signal input terminal (1) is supplied to the mixer (2) and the pulse signal input for contrast adjustment is input. Contrast adjustment pulse signal and brightness adjustment pulse signal input terminal (4) supplied to the terminal (3)
The brightness adjusting pulse signals are supplied to the mixer (2), and the contrast adjusting pulse signal and the brightness adjusting pulse signal are mixed in a predetermined portion of the video signal, for example, in the horizontal blanking period, and the mixture is mixed. The signal is supplied to the gain control amplifier (5), and its output is supplied to the cathode of the cathode ray tube (7) via the video amplifier (6).

In this case, the output of the gain control amplifier (5) is supplied to the sample hold circuit (8), and the contrast adjustment pulse signal input terminal (from the timing signal input terminal (9) supplied to this sample hold circuit (8) ( The sample signal is sampled and held with the sampling signal of the same timing as the pulse signal supplied to 3), and the sampled and held potential is then compared with the comparator (10).
The reference value supplied to the reference signal input terminal (11) is applied to the other input terminal of the comparator (10), and the gain of the gain control amplifier (5) is applied to this comparison output. Is controlled to adjust the contrast of the image displayed on the cathode ray tube (7).

The video amplifier (6) is designed to detect the magnitude of the beam current, and this detection signal is sent to the sample hold circuit (1
2) and the sampling signal with the same timing as the pulse signal supplied to the pulse signal input terminal (4) for brightness adjustment from the timing signal input terminal (13) supplied to this sample hold circuit (12) Hold,
The sampled and held potential is supplied to one input terminal of the comparator (14) and the reference value supplied to the reference signal input terminal (15) is supplied to the other terminal of the comparator (14).
The beam current of the cathode ray tube (7) is controlled by this comparison output,
The brightness of the image displayed on the cathode ray tube (7) is adjusted.

However, with only the configurations of (1) to (15), when the contrast is adjusted by the gain control amplifier (5), the size of the brightness adjustment pulse signal in the output signal naturally changes, so Also changed, and complicated operations such as readjusting the brightness after adjusting the contrast were required.

Therefore, the present applicant has provided a circuit in front of the input terminals (3) and (4) to obtain the required pulse signal for contrast adjustment and the pulse signal for brightness adjustment to eliminate such inconvenience. That is, in FIG. 4, (21) indicates a contrast adjustment signal generation circuit, which supplies a signal of a predetermined potential from the contrast adjustment signal generation circuit (21) to the gate circuit (22) and also the gate circuit (22). A gate signal at a predetermined timing within the horizontal blanking period of the video signal is supplied from the timing signal input terminal (9) to the gate signal input terminal of the contrast signal generation circuit (2
1) Gate a signal of a predetermined level from the gate circuit (22) and obtain a pulse signal of a predetermined level for contrast adjustment at the contrast adjustment pulse output input terminal (3) of the mixer (2) It has been done.

Further, a signal of a predetermined level from the brightness adjustment signal generation circuit (23) is supplied to a multiplier (24) and multiplied with a signal of a predetermined level from the contrast adjustment signal generation circuit (21), and this multiplication signal is supplied to a gate circuit ( 25), and gate with a gate signal of a predetermined timing that does not overlap with the timing signal, and the output side of this gate circuit (25), that is, the brightness adjustment pulse signal input terminal (4) of the mixer (2) A pulse signal for brightness adjustment, which is a signal, is obtained.

According to such a circuit, a pulse signal for contrast adjustment,
Since the contrast and the brightness are adjusted by using the brightness adjustment pulse signal configured to a constant multiple of this pulse signal, the brightness is not affected even when the contrast is adjusted. Since it can be adjusted independently by a simple operation, it is suitable for use in a high-quality color display device or the like.

[Problems to be solved by the invention]

By the way, considering the case where the television receiver is applied to, for example, a color video project, the relationship between the applied voltage between the cathode and the grid of the cathode ray tube and the emission brightness is non-linear, and the red, green, and blue phosphors are used. There is a difference between them, so that there is a problem that the white balance does not apply to all gradations. This problem is particularly noticeable in a projection type color display device with high tube brightness.For example, the saturation of the blue phosphor is faster than that of the other color phosphors, and the phenomenon that the color becomes yellow at the white peak. Appears. However, the circuit configuration of FIG. 4 cannot deal with this problem.

In view of this point, the present invention provides a television receiver capable of adjusting the white balance in all gradations even when applied to a color video projector or the like.

[Means for solving problems]

The television receiver according to the present invention inputs a video signal in which a reference pulse is inserted in a predetermined portion to one of the cathode and the grid of the cathode ray tube (7), detects the level of the reference pulse, and detects the cathode and the grid. In order to adjust the brightness by controlling the other potential of the gamma correction circuit (30) in the video signal system and change the polygonal line characteristic of the gamma correction circuit (30) according to the level of the reference pulse. Is configured.

[Action]

A video signal with a reference pulse inserted in a predetermined part is input to one of the cathode and grid of the cathode ray tube (7), the level of the reference pulse is detected, and the potential of the other of the cathode and grid is controlled to adjust the brightness. To do. Further, the folding line characteristic of the gamma correction circuit (30) inserted in the video signal system is changed according to the level of the reference pulse. This makes it possible to adjust the emission timing of each color and adjust the white balance for all gradations.

[Embodiment] An embodiment of the present invention will be described in detail below with reference to FIGS. 1 to 3.

FIG. 1 shows the entire structure of the present embodiment. In FIG. 1, parts corresponding to those in FIG. 4 are designated by the same reference numerals, and detailed description thereof will be omitted.

In Fig. 1, (1R), (1G) and (1B) are red,
An input terminal supplied with green and blue primary color signals,
The red, green and blue primary color signals from the input terminals (1R), (1G) and (1B) are respectively mixed into mixers (2R), (2G) and (2
The pulse signal for contrast adjustment supplied to the pulse signal input terminal for contrast adjustment (3) and the pulse signal for brightness adjustment supplied to the pulse signal input terminal for brightness adjustment (4) are supplied to the mixer (2R). ), (2G) and (2B)
To a predetermined part of each of the red, green and blue primary color signals,
For example, the contrast adjusting pulse signal and the brightness adjusting pulse signal are mixed in the horizontal blanking period.

The mixer (2R) supplies the red signal, which is a mixture of the pulse signal for contrast adjustment and the pulse signal for brightness adjustment, to the gain control amplifier (5R), and its output is the gamma correction circuit (30R) and video amplifier (6R). It is supplied to the cathode of the red cathode ray tube (7R) via. In this case, the output signal of the gain control amplifier (5R) is the same as the pulse signal supplied from the timing signal input terminal (9R) supplied to the sample hold circuit (8R) to the contrast adjustment pulse signal input terminal (3). Sampled and held with a timing sampling signal, the sampled and held potential is supplied to one input terminal of the comparator (10R), and the reference signal supplied to the reference signal input terminal (11R) is adjusted to a predetermined value. Then, it is supplied to the other input terminal of the comparator (10R), and the gain control amplifier (5
R) gain is controlled so that the contrast of the image displayed on the red cathode ray tube (7R) is adjusted.

Also, the sampling signal of the same timing as the pulse signal supplied from the timing signal input terminal (31R) to the brightness adjustment pulse signal input terminal (3) is applied to the gamma correction circuit (30
R), and the brightness control pulse signal included in the output supplied to the gamma correction circuit (30R) from the gain control amplifier (5R) is extracted, and the gamma correction is performed according to the level of this brightness control pulse signal. Change the bending point of the gamma correction line of the circuit (30R). For example, when the level of the brightness adjusting pulse signal is high (when the brightness is dark), the broken line characteristic of the gamma correction circuit (30R) is shown in FIG.
However, when the level of the brightness adjustment pulse signal is low (when the brightness is bright), the gamma correction circuit (30
The polygonal line characteristic of R) is changed as shown by the broken line b in FIG. 3, so that the bending point of the polygonal line of gamma correction becomes faster.

Further, the video amplifier (6R) is made to be able to detect the magnitude of the beam current, and this detection signal is supplied to the sample hold circuit (12R), and this sample hold circuit (12R)
To the brightness adjustment pulse signal input terminal (13R) from the timing signal input terminal (4R) is sampled and held with the sampling signal of the same timing as the pulse signal supplied to the comparator (14R
) And the reference value supplied to the reference signal input terminal (15R) to the other input terminal of the comparator (14R), and the comparison output is supplied to the red cathode ray tube (7R).
R) to control the beam current of the red cathode ray tube (7R) and adjust the brightness of the image displayed on the red cathode ray tube (7R).

In addition, green signal system circuit (32G) and blue signal system circuit (32G)
As for B), the same circuit as the mixer (2G) and the red signal system circuit (32R) below (2B) should be constructed. However, since the saturation of the blue phosphor is faster than the saturation of the red and green phosphors, the gamma correction circuit has a red signal system circuit (32R) and a green signal system circuit (32G) to correct this. ) Only and not the blue signal system circuit (32B).

FIG. 2 shows an example of a concrete circuit configuration of the gamma correction circuit inserted in the red signal system circuit (32R) and the green signal system circuit (32G). In FIG. ) Connected to the input terminal (40) via the buffer circuit (41) and the resistor (42).
The output side of the buffer circuit (41) is connected to the output terminal (43) connected to
4) One of the main electrodes is connected, the other main electrode of the FET (44) is connected to the non-inverting input terminal of the voltage follower (46) through the resistor (45), and further the voltage follower (46). The non-inverting input terminal of is connected to the ground via the capacitor (47). Further, the control electrode of the FET (44) is connected to the timing signal input terminal (31) via the resistor (48) and the capacitor (49) connected in parallel, and the timing signal input terminal (31) is for brightness adjustment. As described above, the sampling signal of the same timing as the brightness adjusting pulse signal supplied to the pulse signal input terminal (4) (FIG. 1) is supplied.

Also, the inverting input terminal of the voltage follower (46) is interconnected with its own output terminal, and the output terminal is connected to the resistor (50).
Is connected to the switching element, for example, the base of the transistor (51), the base of the transistor (51) is connected to the slider of the variable resistor (53) via the resistor (52), and the variable resistor (53 ) Is connected to the negative power supply terminal -Vcc, the collector of the transistor (5) is connected to the negative power supply terminal -Vcc, and its emitter is connected to the resistor (42) via the variable resistor (54). Connect to the connection point of the output terminal (43).

Considering now that the level of the brightness adjusting pulse signal supplied from the input terminal (4) (Fig. 1) is high, that is, the brightness of the image displayed on the cathode ray tube is dark, the timing signal input terminal (31 The sampling signal supplied to the buffer circuit (4) is supplied to the FET (44).
The pulse signal for brightness adjustment included in the output from 1) is extracted and supplied to the base of the transistor (51) via the voltage follower (46). This transistor (51) turns on and the line characteristic of the gamma correction circuit. Is bent, for example, as shown by the solid line a in FIG. The slope of the polygonal line characteristic is determined by the division ratio of the resistor (42) and the variable resistor (54).

On the other hand, when the level of the brightness adjustment pulse signal supplied from the input terminal (4) (FIG. 1) becomes lower than this state, that is, when the brightness of the image displayed on the cathode ray tube becomes brighter,
The level of the brightness adjustment pulse signal extracted by the FET (44) decreases, and accordingly the voltage follower (4
Since the output level of 6) will also be low, the base potential of the transistor (51) will be low, and the transistor (51) will turn on sooner than in the previous state, that is, when the level of the brightness adjustment pulse signal is high. The broken line characteristic of the gamma correction circuit is as shown by the broken line b in FIG. 3, and the bending point of the broken line is earlier than in the previous state. As a result, the balance of red and green emission with respect to blue is adjusted, and the white balance of all gradations, especially the white peak and the halftone, is adjusted.

〔The invention's effect〕

As described above, according to the present invention, the polygonal line characteristic of the gamma correction circuit inserted in the video signal system is changed according to the level of the reference pulse inserted in the predetermined portion of the video signal, that is, the brightness adjusting pulse signal. The white balance can be adjusted in all the gradations, and for example, the saturation of the blue phosphor is faster than the others, so that the phenomenon such as yellowing of the color at the white peak is prevented. There is also the advantage that the white balance does not change even if the brightness is adjusted.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention, FIG. 2 is a circuit block diagram showing an example of a main part of the present invention, and FIG. 3 is a diagram for explaining the operation of FIG. 1 and FIG. A characteristic diagram and FIG. 4 are configuration diagrams showing an example of a conventional example. (1R), (1G) and (1B) are input terminals for red signal, green signal and blue signal respectively, (2R), (2G) and (2B) are mixers respectively, and (4) is a pulse signal for brightness adjustment Input terminal, (6
R) is a video amplifier, (12R) is a sample and hold circuit, (14R) is a comparator, (30R) is a gamma correction circuit,
(32R), (32G) and (32B) are red signal system, green signal system and blue signal system circuit, respectively.

Claims (1)

[Claims] 1. A video signal having a reference pulse inserted in a predetermined portion is input to one of a cathode and a grid of a cathode ray tube, the level of the reference pulse is detected, and the potential of the other of the cathode and the grid is controlled. The television receiver is characterized in that brightness adjustment is performed and a gamma correction circuit is inserted in the video signal system, and a polygonal line characteristic of the gamma correction circuit is changed according to the level of the reference pulse.