JP2636831B2 - Receiver - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a television receiver.

[Conventional technology]

In a television receiver, adjustment or correction of the following four items is necessary to correctly perform vertical deflection in the picture tube. That is: i Adjustment of vertical deflection size ii Adjustment of vertical deflection center iii Adjustment of S-shape iv Adjustment of symmetry And adjustment of the i-th term adjusts the amplitude H ₀ of the vertical deflection signal Sh shown in FIG. 2A. done by adjustment of the ii term is carried out by adjusting the DC level a ₀ of the signal Sh. In addition, the correction in the paragraph iii
And a sine wave signal Ss as shown in FIG.
Performed by adjusting the amplitude S ₀ of the signal Ss. Further, adjustment of the iv term, as well as adding a parabolic signal Sp as shown in Figure C signal Sh, is performed by adjusting the amplitude S ₁ of the signal Sp.

[Problems to be solved by the invention]

Therefore, when the adjustments of the vertical deflection size in the television receiver (the i section), since the amplitude H ₀ of the signal Sh has changed, the value A ₀ corresponding to the change in the amplitude H _0, It is necessary to readjust S ₀ and S ₁ .If these values A ₀ , S ₀ and S ₁ are not readjusted or readjustment is insufficient, the deviation of the vertical deflection position and the screen (S-shape correction and symmetry) are caused.

Therefore, when adjusting the vertical deflection size, it is necessary to repeat the adjustment of the size and the adjustment of the values A ₀ , S ₀ , and S ₁ many times, which requires skill and requires a lot of adjustment time. I need it. In addition, a test pattern generator is required for adjustment, and a service person cannot easily make adjustments at a repair site.

This invention, when adjusting the vertical deflection size,
No need to make other adjustments, resulting in vertical deflection position deviation or screen distortion, no need for a lot of adjustment time for other adjustments, and no use of test pattern generator The purpose of the present invention is to make it possible to easily adjust the vertical deflection size.

[Means for solving the problem]

Thus, the inventors have determined that the vertical deflection size and value H ₀ , A ₀ ,
Experiments on S ₀ and S ₁ yielded the following related equations.

That is, when adjusting the vertical deflection size, the signal
The amplitude H ₀ of Sh is changed. At this time, if the values A ₀ , S ₀ , and S ₁ are simultaneously changed with respect to the change of the amplitude H ₀ as shown by the equation (v), the center position of the vertical deflection is obtained. It turned out that only the vertical deflection size can be adjusted without shifting or distorting the screen (the figure is an example for a 27-inch TV receiver).

Focusing on such a point, the present invention deflects the amplitude H _{0 of the} signal Sh to adjust the size when adjusting the vertical deflection size, and also adjusts the values A ₀ , S ₀ , S according to the equation (v). ₁ is changed at the same time.

[Action]

Therefore, according to the present invention, when adjusting the vertical deflection size, it is only necessary to operate a key or a knob for the adjustment, and there is no need to operate other keys and knobs at all. Can be easily done in a short time, and no skill is required. Further, a test pattern generator or the like is not required.

〔Example〕

The example shown in FIG. 1 has a configuration of a so-called digital television. In FIG. 1, reference numeral 11 denotes a tuner circuit having from a synthesizer type tuner to a video detection circuit. Extracts a composite video signal. And this signal is A / D
Is supplied to the converter (21) is a digital signal, this signal is supplied to a peaking filter (32) is a digital luminance signal Y _D is taken out through the comb filter (31), the signal Y _D processing circuit ( 33) After being supplied to the D / A converter (23Y)
Is supplied to an analog luminance signal Y. This signal Y
Is supplied to the matrix circuit (24).

The output of the filter (31) is supplied to a band pass filter (34) is a carrier chrominance signal C _D digital taken out, the signal C _D is supplied to the processing circuit (35) with ACC, hue, color ( digital color difference signals of red and blue (R _D -Y _D), the (B _D -Y _D) is demodulated is supplied from the adjustment is performed, such as color saturation) the color demodulation circuit (22), these The signal is D /
The color signals are supplied to A converters (23R) and (23B) to be analog color difference signals (RY) and (BY), and these signals are supplied to a matrix circuit (24).

Then, from the matrix circuit (24), the three primary color signals R,
G and B are extracted, and these signals are used as white balance amplifiers (25R), (25G), (25B) and dry amplifiers (1
2R), (12G), and (12B) are supplied to the color picture tube (13).

Further, (40) indicates a deflection circuit, and a tuner circuit (1
The signal from 1) is supplied to a sync separation circuit (41) to extract a horizontal sync pulse, and this pulse is converted to a shaping circuit (42).
Is supplied to a pulse having a predetermined pulse width and phase,
This pulse is supplied to a horizontal output circuit (16) to be a horizontal deflection signal, and this signal is supplied to a deflection coil (15). Further, a composite synchronization pulse is extracted from the separation circuit (41), the pulse is supplied to an integration circuit (43), a vertical synchronization pulse is extracted, and the pulse is supplied to a shaping circuit (44) to have a predetermined pulse width. and is the phase of the pulse, the pulse is a vertical deflection signal S _V is supplied to the vertical output circuit (17), the signal S _V is supplied to the deflection coil (15).

At this time, the vertical synchronizing pulse from the integration circuit (43) is supplied to the formation circuit (45) to form correction signals Ss and Sp, and these signals Ss and Sp are output to the output circuits (16) and (17). The supplied horizontal and vertical deflection signals are corrected to an appropriate waveform.

Numerals (50) and (60) denote 8-bit processing microcomputers. Non-volatile memories (72) and (73) are connected to these microcomputers (50) and (60), respectively. ) Is connected to a key panel (71). This key panel (71) allows users to select channels,
It has a plurality of keys for adjusting (changing) hue and color. The memory (72) is for storing channel selection data preset on the numeric keypad of the panel (71) and data such as hue and color adjusted by the user even when the power is turned off. . However, data such as hue and color stored in the memory (72) is an offset value with respect to a standard value (center value), and the standard value is stored in the memory (73). Further, the memory (73) also stores data that does not require adjustment by a user, such as data on white balance, horizontal and vertical deflection (for example, linearity), but requires adjustment by a manufacturer or service person. You. The data in the memory (73) is supplied to the commander (75) for adjustment by the manufacturer or serviceman through the connector (76).
When connected to the microcomputer (60) through the commander (7
5) is written to the memory (73).

When the power is turned on, the microcomputer (50) retrieves the data of the channel selected before the power was turned off from the memory (72) by the microcomputer (50).
The channel selected before turning off the power is subsequently selected, and the microcomputer (60) retrieves the white balance data from the memory (73) by the microcomputer (60). Amplifier (25
R) to (25B), the signals RB are corrected so that white balance can be obtained.

Further, the microcomputer (60) retrieves horizontal and vertical deflection data from the memory (73), and this data is transmitted to the circuits (42), (44), (4) through the interface (49).
5), the horizontal and vertical deflection waveforms are adjusted (corrected) to correct waveforms. The microcomputer (60) retrieves standard value data such as hue and color from the memory (73), and the microcomputer (50) retrieves the memory (72).
The data of the offset value such as hue and color is extracted from the
The data is supplied to the microcomputer (60) through (74), the offset value data is added to the standard value data in the microcomputer (60), and the data having this offset is processed through the interface (39) through the processing circuits (33) and (35). ), The signals Y _D , _CD are adjusted to the hue and color signals adjusted by the user.

Therefore, the value selected when the power was turned off can be viewed in the same state as at that time.

The data supplied to the interfaces (29), (39), and (49) are stored in the registers provided in the interfaces (29), (39), and (49) until new data is supplied next. (Not shown).

When the user operates, for example, a numeric keypad on the panel (71), the microcomputer (50) retrieves the data of the channel preset for the operated key from the memory (72), and transmits the data to the tuner circuit (11). ) And the channel specified by the ten keys on the panel (71) is selected. At this time, data indicating the newly selected channel is written to the memory (72) and is provided at the time of the next power-off.

When a hue key on the panel (71) is operated, for example, the hue offset value data in the memory (72) is updated each time the key is operated, and the data is transmitted to the microcomputer (60) via the interface (74). The data having the offset is supplied to the processing circuit (35) through the interface (39), and the hue adjustment is performed.

Further, the adjustment of the vertical deflection size is performed by a manufacturer or a serviceman, and this is performed by the commander (75) as follows.

That is, when the commander (75) is connected to the connector (36), this is determined by the microcomputer (60), and the receiver enters the adjustment mode. The commander (75) has various adjustment keys as shown in FIG. 3, for example. When the vertical deflection size key VSIZ is pressed among these keys,
This is determined by the microcomputer (60), and the receiver enters the vertical deflection size adjustment mode among the adjustment modes.

Therefore, pressing the up key UP of the commander (75), which is changed by one step of the data is judged value H ₀ to S ₁ in accordance with (v) expression by the microcomputer (60), these data circuits ( 44) (with supplied amplitude H ₀ of the vertical deflection signal S _V is increased by one step in 45), the value a ₀ and signal Ss, the amplitude S _0, S ₁ is (v) expression of Sp Therefore, it is increased by one step. Further, when pressing the down key DOWN of the commander (75), together with the amplitude H ₀ of the signal S _V in the reverse change is reduced by one step, the value A _0, S _0, S ₁ is (v) Formula Is reduced by one step.

Therefore, each time the key UP or DOWN is pressed, the vertical deflection size increases or decreases by one step each time. At this time, the center position of the vertical deflection does not shift or the screen is not distorted.

And when the vertical deflection size can be adjusted to an appropriate value,
Pressing the enter key ENTR the commander (75), data indicating the value H ₀ to S ₁ at this time is written into the memory (73).

The next time the power is turned on, this new data is retrieved and used for vertical deflection.

 The above is the operation at the time of adjusting the vertical deflection size.

Actually, the parts enclosed by the chain lines, that is, the circuits (21) to (29), (31) to (39), (41) to (49)
Each of them is integrated into one IC (20), (30), and (40), and specific products include, for example, IC (20) ... VCU2100 (ITT) IC (30) ... ... CVPU2210 (ITT) IC (40) ... DPU2500 (ITT) IC (60) ... CCU2000 (ITT) IC (73) ... MDA2061 (ITT) Sy
stem ", published by ITT).

Thus, according to the present invention, when adjusting the vertical deflection size, it is only necessary to operate the adjustment key or knob, and it is not necessary to operate the other keys and knobs at all. Can be easily done in a short time, and no skill is required. Further, a test pattern generator or the like is not required.

It should be noted that horizontal pincushion distortion can also be corrected. According to experiments, Met.

〔The invention's effect〕

According to the present invention, when adjusting the vertical deflection size,
It is only necessary to operate the adjustment keys or knobs, and it is not necessary to operate other keys and knobs at all, so it is easy to adjust the vertical deflection size in a short time, and it requires skill. do not do. Further, a test pattern generator or the like is not required.

[Brief description of the drawings]

FIG. 1 is a system diagram of an example of the present invention, and FIGS. 2 and 3 are diagrams for explanation thereof. (20), (30), (40), (50) and (60) are ICs.

Continued on the front page (72) Inventor Takashi Ichikawa 6-7-35 Kita-Shinagawa, Shinagawa-ku, Tokyo Sony Corporation (72) Yoshiki Komiya Inventor 6-7-35 Kita-Shinagawa, Shinagawa-ku, Tokyo Sonny (56) References JP-A-49-107625 (JP, A) JP-A-53-94831 (JP, A) Jpn.

Claims (1)

(57) [Claims] When the first adjustment item, which is the adjustment of the vertical deflection size, is adjusted, a vertical deflection center adjustment, an S-shaped correction,
A first adjustment that requires adjustment of a second adjustment item, which is one of symmetry adjustments, and wherein the adjustment of the first and second adjustment items has a common variable that is the amplitude of the vertical deflection signal, respectively.
And when represented by the second mathematical expression, the second adjustment item is also adjusted simultaneously using the second mathematical expression when adjusting the first adjustment item.