JPH07199882A - Chromaticity adjustment circuit - Google Patents

Abstract

PURPOSE:To provide a chromaticity adjustment circuit realizing the simplification of chromaticity adjustment and precise color tracking from high luminance to low luminance in a CRT color display monitor. CONSTITUTION:This circuit is provided with a preamplifier circuit 1, a gain control circuit 5, a low luminance part chromaticity adjustment circuit 10 and an offset level adjustment circuit 11. By providing the low luminance part chromaticity adjustment circuit 10 in addition to the gain control circuit 5 deciding the gain of the preamplifier circuit 1, and making the output voltage of the low luminance part chromaticity adjustment circuit 10 the offset of the output voltage of the gain control circuit 5 in the offset level adjustment circuit 11, the excellent color tracking from high luminance to low luminance is attained. In this case, the gain control circuit 5 means a circuit block modulating cathode voltages applied to respective cathode electrodes R, G, B of a color CRT.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a chromaticity adjusting circuit for a high definition color display monitor which requires good color tracking from high brightness to low brightness.

[0002]

2. Description of the Related Art FIG. 2 is a circuit diagram showing a conventional chromaticity adjusting circuit in a video signal amplifying circuit.
2 is a video output circuit, 3 is a DC reproducing circuit, 4 is a CRT, 5
Is a gain control circuit, 6 is a high brightness portion chromaticity adjustment circuit, 7 is a contrast control unit, 8 is a cutoff voltage adjustment circuit, and 9 is a brightness control unit. Note that FIG.
Similar to the above, only the R channel is shown, but the G and B channels have similar circuit configurations. Also,
The outputs of the contrast control unit 7 and the brightness control unit 9 are commonly connected to the R, G, and B channels.

The operation principle of the chromaticity adjusting circuit of the CRT color display monitor, which has the same circuit for the cutoff voltage adjustment and the chromaticity adjustment for the low luminance area as described above, will be described.

First, in the cutoff voltage adjusting circuit 8,
The Bach cluster chromaticity is determined by adjusting the R, G, and B cutoff voltages. Next, the voltages V _{subcont (R)} , V _{subcont (G)} , and V controlled by the high luminance part chromaticity adjustment circuit 6 are controlled.
The output voltage of the gain control circuit 5 is modulated by _{subcont (B)} , and the amplification degree of the preamplification circuit 1 is determined. The contrast control unit 7 and the brightness control unit 9 can operate the contrast and brightness of the screen.

Based on the above, the output voltage V of the preamplifier circuit
_(R) , V _(G) , and V _(B) are represented as follows by the high-luminance part chromaticity adjustment circuit output voltage and the contrast control voltage V _cont .

[0006] <Formula _{-1> V (R) = A} (R) · V subcont (R) · V cont V (G) = A (G) · V subcont (G) · V cont V (B) = A _(B) -V _{subcont (B)} -V _cont * A _(R) , A _(G) , and A _(B) are gains specific to the linear amplifier.

In the above equation, the contrast control voltage V _cont is
Since the R, G, and B channels change at the same rate, the ratio of the preamplifier output voltages V _(R) , V _(G) , and V _(B) is A _(R).
・ V _{su bcont (R)} , A _(G)・ V _{subcont (G)} , A _(B)・ V
It is determined by the ratio of _{subcont (B)} . Originally, the chromaticity is determined by the ratio of the primary color signals R, G, B, and in the display device using the CRT, it is determined by the ratio of the voltages applied to the R, G, B cathode electrodes. Therefore, even if the contrast and the brightness change, the chromaticity does not change as long as the ratio of V _(R) , V _(G) , and V _(B) is kept constant.

[0008]

However, the above-mentioned conventional circuit has the following two problems.

First, the contrast control voltage V
_{When cont} is the maximum, that is, the chromaticity of the maximum brightness is determined by the output voltages V _{subcont (R)} , V _{subcont (G)} , and V of the high brightness part chromaticity adjustment circuit.
_{When the} target value is set by _{subcont ( B)} , the ratio of the preamplifier output voltages V _(R) , V _(G) , V _(B) is ideally when _Vcont is minimum, that is, the minimum brightness. The same is true for, and the chromaticity is also unchanged. However, the gain of the linear amplifier is V
Due to various factors such as not being linear with respect to changes in _cont , the chromaticity that was set as the target value in the high-luminance portion is not accurately reproduced in the low-luminance portion.

For the above reasons, the cutoff voltage adjusting circuit 8 adjusts the chromaticity of the low-luminance portion as a means for realizing good chromaticity reproducibility not only in the high-luminance portion but also in the low-luminance portion. Was. However, since the cut-off voltage determines the bat cluster chromaticity, if the cut-off voltage is manipulated by prioritizing the color accuracy in the low-brightness area, the bat cluster chromaticity deviates from the target value, and It had a problem of sticking.

Secondly, the chromaticity adjustment procedure in the conventional circuit is shown below. First, with the cutoff voltage adjusting circuit 8,
The cutoff voltage of each of R, G, and B is adjusted to set the back cluster chromaticity at the time of no signal to the target value. Next, the high luminance part chromaticity adjustment circuit 6 adjusts the chromaticity at the maximum luminance, and the cutoff voltage adjustment circuit 8 further performs the chromaticity adjustment at the minimum luminance. Here, since the chromaticity adjustment of the low-luminance portion is performed by the cutoff voltage adjustment circuit 8, R,
Each of the G and B cutoff voltages deviates from the previously set target value, causing a problem in the back cluster chromaticity.

Further, the chromaticity adjustment of the high-luminance portion is carried out with the back cluster chromaticity adjusted to the target value, but the R, G, and B cutoffs are made by the chromaticity adjustment of the low-luminance portion. Since the voltage is readjusted, the chromaticity of the high-luminance portion also deviates from the target value, and it is necessary to reset the chromaticity of the high-luminance portion to the target value again.

As described above, in the conventional circuit, the chromaticity of the low-luminance portion and the high-luminance portion influences each other in the chromaticity adjustment of the low-luminance portion and the high-luminance portion. This operation needs to be repeated until the light is focused on, which causes a problem that it takes a lot of time to adjust the chromaticity.

[0014]

In order to solve such a problem, the present invention comprises a cut-off voltage adjustment and a chromaticity adjustment of a low luminance portion which are independent circuits, and a chromaticity adjustment of a low luminance portion and a high luminance portion. The luminance part chromaticity adjustment and the cut-off voltage adjustment can be performed independently, and an OFF SET LEVEL adjustment circuit is provided to adjust the zero points of the R, G, and B voltages. The cutoff voltage adjusting circuit controls the DC voltage applied to the DC reproducing circuit, and the low luminance part chromaticity adjusting circuit controls _{Vlow (R)} , _{Vlow (G)} , and _{Vlow (B) in FIG.} In the high brightness part chromaticity adjustment circuit, V _{subcont (R)} , V
_{It controls subcont (G)} and V _{subcont (B)} . In the gain control circuit, the above V _{subcont (R)} , V _{subcont (G)} , V
_{subcont (B)} and V _cont which is controlled by the contrast control section are _{combined, V subcont (R) · V} cont, V subcont (G) · V
_cont , V _{subcont (B)} · V _cont are output. Furthermore, OFF
In the SET LEVEL adjusting circuit, the output voltages V _{low (R)} , V _{low (G)} , and V _{low (B )} of the low luminance part chromaticity adjusting circuit are changed to the gain control circuit output voltages V _{subcont (R)} · V _cont , V _{subcont. (G)}・ V _cont ,
It is configured to operate as an offset voltage of V _{subcont (B)} · V _cont .

[0015]

[Function] The chromaticity adjustment of the low luminance part, the chromaticity adjustment of the high luminance part, and the cutoff voltage adjustment are operated by independent circuits, thereby eliminating the mutual influence during the adjustment and greatly shortening the adjustment time. Can be achieved. In addition, by separating the low-luminance part chromaticity adjustment circuit and the cutoff voltage adjustment circuit, the back cluster chromaticity does not collapse after the low-luminance part adjustment, and the low-luminance part chromaticity adjustment circuit output voltage is gain controlled. By using the offset voltage of the circuit output voltage, the zero points of the R, G, and B cathode voltages are adjusted, and good color tracking from low brightness to high brightness can be obtained.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT FIG. 1 shows a CRT color display according to the present invention.
One example when applied to a monitor, please refer to the drawings
While explaining. 1 is a preamplifier circuit, 2 is a video output circuit
Path, 3 is a DC regeneration circuit, 4 is a CRT, 5 is a gain control circuit
, 6 is a chromaticity adjusting circuit for high luminance part, 7 is contrast control
Section, 8 is a cutoff voltage adjusting circuit, 9 is a brightness control
Control part, 10 is a low-brightness part chromaticity adjustment circuit, 11 is OFF SET LE
It is a VEL adjustment circuit. Note that FIG. 1 shows only the R channel.
Although it is listed, the same applies to the G channel and B channel.
It is a circuit configuration of. Furthermore, the contrast control unit 7 and the
The output of the lightness control unit 9 is output for each of the R, G, B channels.
Connected to the public. High brightness from the high brightness part chromaticity adjustment circuit 6.
Specific voltage V for achieving the target chromaticity during chromaticity adjustment
_{subcont ( R)}, V_{subcont (G)}, V_{subcont (B)}Is output
It Further, the low-luminance part chromaticity adjustment circuit 10
Specific voltage V for achieving the target chromaticity during adjustment_{low (R)}，
V_{lo w (G)}, V_{low (B)}Is output. Output of gain control circuit 5
Force voltage V_{subcont (R)}・ V_cont, V_{subcont (G)}・ V_cont，
V_{subcont (B)}・ V_contIs the output of the high brightness part chromaticity adjustment circuit 6.
Force voltage V_{subcont (R)}, V_{subcont (G)}, V_{subcont (B)}When,
A controller commonly connected to the R, G, and B gain control circuits 5.
Output voltage V of trust control unit 7_contA composite of and
Is. Furthermore, in the OFF SET LEVEL adjustment circuit 11,
Output voltage V of gain control circuit 5_{subcont (R)}・ V_cont, V
_{subcont (G)}・ V_cont, V_{subcont (B)}・ V _contAnd low brightness
Output voltage V of the partial chromaticity adjustment circuit 10_{low (R)}, V_{low (G)}, V
_{low (B)}Zero point adjustment with
Is amplified. Video signal amplification configured as above
In the circuit, set the gain of OFF SET LEVEL adjustment circuit 11
Assuming that B is the output voltage of the preamplifier circuit of this embodiment,
It can be expressed as -2.

<Formula-2> V_(R)= B_(R)(A_(R)・ V_{subcont (R)}・ V_cont+ V
_{low (R)}) V_(G)= B_(G)(A_(G)・ V_{subcont (G)}・ V_cont+ V
_{low (R)}) V_(B)= B_(B)(A_(B)・ V_{subcont (B)}・ V_cont+ V
_{low (R)}) According to this circuit configuration from the above equation, when brightness is constant,
Change in brightness is V_contAnd the image is V_contWhen the smallest
Small brightness, V_contMaximum brightness at maximum. Yo
V_contIn the low luminance part where the value of
Also V_contSince it decreases in proportion to V,_(R), V_(G), V
_(B)V in_{low (R)}, V_{low (G)}, V_{low (B)}Is greatly affected
Kiku, V_(R), V_(G), V_(B)The ratio of V_{low (R)}, V
_{low (G)}, V_{low (B)}Since it is equal to the ratio of
The chromaticity is the adjusted value itself. In addition, the adjustment of high brightness
In order, V_{low (R)}, V_{low (G)}, V_{low (B)}Determined the value of
Later V_{subcont (R)}, V_{subcont (G)}, V_{subcont (B)}The value of the
V to determine_{low (R)}, V _{low (G)}, V_{low (B)}Voltage
The value acts as an offset voltage for each of R, G and B.
It The above formula is V_contIs a linear function of_cont
Since the target chromaticity is set at the maximum and minimum times, the CRT
The output image should have a good color track from high to low brightness.
It is possible to get the King.

Next, the chromaticity adjusting method in FIG. 2 will be described. First, in the cutoff voltage adjusting circuit 8, R, G,
B Each cathode voltage is manipulated to adjust the Bach cluster chromaticity when there is no signal. Next, in the low brightness part chromaticity adjustment circuit 10, the chromaticity at the minimum brightness is set to the target value,
The values of V _{low (R)} , V _{low (G)} and V _{low (B)} are determined. At this time, the _values of V _{subcont (R)} , V _{subcont (G)} , and V _{subcont (B)} are minimized. Then, in the high luminance part chromaticity adjusting circuit 6, V _subcon is set so that the chromaticity at the maximum luminance becomes the target value.
The values of _{t (R)} , V _{subcont (G)} and V _{subcont (B)} are determined. This completes all adjustments, but since each adjustment is made up of independent circuits, there is no mutual effect and the need to re-adjust the parts that have been adjusted once is eliminated. It can be shortened.

[0019]

As described above, according to the present invention, in the chromaticity adjusting circuit of the video signal amplifier circuit, the cutoff voltage adjusting circuit, the low luminance part chromaticity adjusting circuit, and the high luminance part chromaticity adjusting circuit are made independent. Furthermore, by providing an OFF SET LEVEL adjustment circuit, good color tracking can be obtained from low brightness to high brightness, and the chromaticity adjustment time can be greatly shortened.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing an embodiment of a chromaticity adjusting circuit of the present invention.

FIG. 2 is an explanatory diagram showing a conventional technique of a chromaticity adjustment circuit.

[Description of Reference Signs] 1 preamplifier circuit 2 video output circuit 3 DC reproduction circuit 4 CRT 5 gain control circuit 6 high brightness part chromaticity adjustment circuit 7 contrast control part 8 cutoff voltage adjustment circuit 9 brightness control part 10 low brightness part Chromaticity adjustment circuit 11 OFF SET LEVEL adjustment circuit

Claims (1)

[Claims] 1. A cutoff voltage adjusting circuit, a low luminance part chromaticity adjusting circuit, a gain control circuit, and an OFF circuit are provided as means for controlling the electron beam amount of a color CRT by the voltage difference applied between G1 and the cathode. Chromaticity adjustment circuit characterized by having a SET LEVEL adjustment circuit and making each independent.