JPH0230276A - Contour correction circuit - Google Patents

Abstract

PURPOSE:To attain clear contour emphasis with less noise by operating a sharpness control circuit and a speed modulation circuit interlockingly with each other so as to apply the contour emphasis. CONSTITUTION:A TV signal received by an antenna 10 is fed to a video signal processing circuit 19 and a color signal processing circuit 16 via a tuner 12 and a demodulation circuit 14. Furthermore, a synchronizing signal separated from a video signal is fed to a deflection circuit 24 and the speed modulation circuit 29. The output frequency characteristic of the video signal processing circuit 19 is changed by adjusting a variable resistor 32. The correction quantity of the speed modulation circuit 29 is changed in interlocking with the adjustment of the output frequency characteristic (sharpness) in the video signal processing circuit 19. Clear contour emphasis is attained without much emphasis in the frequency of 1-3MHz including remarkable noise by the video signal processing circuit 19.

Description

DETAILED DESCRIPTION OF THE INVENTION (A) Field of Industrial Application The present invention relates to a contour correction circuit for a television receiver.
Special C=concerns a nine-contour correction circuit using a scanning speed modulation circuit.

(b) Prior Art It is well known in the art to use scanning speed modulation circuits to enhance the sharpness of images.

For example, such a device is disclosed in Utility Model Publication No. 60-19407 (H
D4N shi 32), special public Sho b5-992 (I (04N5
/44) etc.: 2 shown 0 And the drawback of this scanning speed modulation circuit is the size of the image projected on the picture tube (2).
The effect is greatly influenced by the brightness (brightness) and frequency characteristics. In other words, depending on the input video signal, the optimum effect of scanning speed modulation C2 may not be obtained.

For this reason, conventionally, the magnitude and frequency characteristics of the input video signal are detected, and according to the detection results,
It has been proposed to always perform optimal contour correction by changing the effect of scanning speed modulation (Japanese Patent Laid-Open No. 62-25457).
No. 6 H04N5/208).

By the way, the television receiver C; is based on the user's preference C.
Second, adjustment knobs for adjusting brightness and sharpness are provided.

A conventional general television receiver equipped with such adjustment means such as adjustment knobs is shown in FIG. 8C-2.

The opening in Figure 8 only shows the sharpness knob ξ for adjusting the sharpness, and the brightness level adjusting means is omitted. 90α1 is an antenna, α is a tuner, r14 is a demodulation circuit,
ae is the color circuit, α peak is the video processing circuit, (1) is the matrix circuit, ■ is the picture tube, @ is the deflection circuit, (1) is the main deflection yoke, ■ is the speed modulation circuit, and ■ is the auxiliary deflection yoke. . R3 is a sharpness knob Z+; it is a variable resistor that is adjusted accordingly. This variable resistor C37J (32) controls the sharpness control circuit in the video processing circuit aS to vary the frequency characteristics of the video signal.■ in FIG. 9(a) indicates the variable resistor G? i indicates the frequency characteristic of the output video signal of the video processing circuit aυ in the central part,
■ in Figure 9(a) is M! L! (highest) part (7) f
%'&, and ■ in FIG. 9(a) indicates the f characteristic at the Min (lowest) portion.

FIG. 9c'b) shows the frequency correction amount by the speed modulation circuit 1281+=.

Therefore, the f-characteristic of the image projected on the picture tube sphere is a composite of FIGS. 9(a) and (1), and has the characteristic shown in FIG. 9(0).

As can be seen from the characteristic diagram in FIG. 9(a), in conventional television receivers (2), when the sharpness knob is operated and the variable resistor (33y Max section ζ:''A is adjusted, 1~
The frequency component of 3MEl is high, exceeding Table 9, and the noise around 1 to 3 MHz, which is most noticeable on the screen, is also emphasized, resulting in a very noisy screen.

Also, if a friend (not shown) manipulates the brightness adjustment knob to increase the brightness of the picture tube and make it darker, the area where the speed modulation is effective will shine white and stand out, making the screen difficult to see. .

(c) Problems to be Solved by the Invention The present invention provides a contour correction circuit that can perform optimal speed modulation even when brightness and sharpness are adjusted.

Ninth Means for Solving the Problem The present invention comprises a sharpness control circuit that completely corrects the contour portion of a video signal and outputs it to a picture tube @, and a sharpness control circuit that controls the correction t in 48. a sharpness adjustment means G and a speed modulation circuit (29) that outputs a speed modulation signal to the deflection yoke (7) in order to perform contour correction by varying the scanning speed of the electron beam on the contour portion of the video signal; In the contour correction circuit provided, the frequency band for correction by the sharpness control circuit (c) is made higher than the frequency band for correction by the speed modulation circuit (:, the sharpness adjustment means C3a C
The speed modulation circuit c! I is also a contour correction circuit that emphasizes contours.

The present invention also provides a brightness level adjusting means (56) for adjusting the brightness of the image displayed on the picture tube r:nJC2, and a speed adjusting means (56) for adjusting the brightness of the image projected on the picture tube r:nJC2, and a speed adjusting means (56) for adjusting the scanning speed of the electron beam for the contour part of the video signal to perform contour correction. In the contour correction circuit equipped with a speed modulation signal output for outputting a modulation signal to the deflection eye, the brightness level adjusting means (56) also controls the speed modulation circuit (29), This is a contour correction circuit that reduces the level of the speed modulation signal when the brightness is low.

(e) Function: When adjusting the sharpness, the present invention links the sharpness control circuit (481) and the speed modulation circuit 3 to perform contour enhancement that makes noise less noticeable.

In addition, the present invention adjusts the brightness and darkness of the screen by means of a brightness level adjusting means (56) (2), and varies the speed modulation effect to make it optimal.

(F) Embodiment Referring to FIGS. 1 and 2, a first embodiment of the present invention is shown. In addition, parts C that are the same as those in FIG. 8 are given the same reference numerals.

In FIG. 1(2), αQ is an image processing circuit, and the adjustment value of the variable resistor C21; accordingly, its output f characteristic becomes as shown in FIG. 2(a). ) (b
This is f special at the inside part. As can be seen from FIG. 2(a), this circuit αl emphasizes a relatively high frequency band of 3MI (2 or more) compared to the circuit (18C) of FIG.

1 is a speed modulation circuit, and its correction amount changes according to the adjustment value of the variable resistor G. Its characteristics are shown in Figure 2 ('b
).

Therefore, the f characteristic above the picture tube is as shown in FIG. 2 (-).

In other words, without emphasizing the frequency of 1 to 3MT (K) containing noticeable noise in the video processing circuit a9, as shown in FIG.
The outline of the velocity modulation signal line is shown with reference to FIG. 3. (
(b) is an input terminal into which a video signal is input, (7) is a differentiation circuit, (to) is an amplification control circuit, and (IQ is an output circuit).

(4) is a control circuit in the amplification control circuit (421), and the gain of this control circuit (421, not shown) is controlled by the DO control signal from the variable resistor (1) shown in FIG.

By adjusting a variable resistor (not shown), the amount of current flowing through the auxiliary deflection can be adjusted, and the effect of scanning speed modulation C can be adjusted.

Another example of the scanning intensity modulation circuit will be outlined with reference to FIGS. 4 and 5. In addition, in Book 4, Book 2, No. 5
Identical parts I to those in the figure are given the same reference numerals.ft.

(44 is a phase adjustment circuit that adjusts the delay amount of the speed modulation signal. (46) is an amplification control circuit. (43 is an integrated circuit that controls the amplification degree) It is a circuit (work 0), and specifically, it is "AN614J", an IO for video amplifier and modulation/demodulation manufactured by Matsushita Electric Industrial Co., Ltd.

This input terminal (b) inputs a nine video signal (1), which is amplified by a transistor and then (2, differentiating circuit f36). This speed modulation signal outputs
is input to. In the amplification control circuit (to), the two-speed modulation signal from the ■ pin C is input and output from the ■ pin.

Then, D by the variable resistor (Fig. 1 32) to the ■ pin.
o Control signal (2) changes the output level of the aforementioned pin. This increases the amplifier circuit (2) changes the output signal level 2, and the output circuit (varies the current flowing through the auxiliary deflection yoke in 4Q). , the effectiveness of speed modulation can be adjusted.

Furthermore, the fifth (ilh=I o(421r A N 61
4 J ID internal equivalent circuit diagram is shown in the circle for reference.

Referring to FIGS. 6 and 7, the scanning speed modulation circuit and sharpness control circuit! 48 is shown schematically.

In FIG. 6, the same parts as in FIG. 1 and FIG. 4 are denoted by the same reference numerals, and FIG.

First, I will explain the sharpness control circuit using a delay line.

When a video signal with a waveform as shown in FIG. 7 (IL) j2 is input and passes through the delay line (D L 1 ) via the emitter of the transistor (ql), this signal is converted to the signal shown in FIG. 7 c'b). It becomes like this. Here, day line (D
The input side of L 1 ) is matched with the resistor (R4) by the resistor (R4), but the output side has a high impedance and a reflected wave is present. This reflected wave returns to the input side f2 and is connected to the delay line (DI).

The waveform at the input end of 1) is as shown in FIG. 7 (Q).

The signals shown in FIGS. 7(C) and (b) are input to the bin 10 (IO2). This lo(102) is rAN614J manufactured by Kenko as described above. This IO takes the difference between the signals input to bins ① and ②, adjusts the amplitude of the difference signal according to the DO voltage applied to bin 0, and outputs the signal from each bin. Therefore, by adjusting the variable resistor 03 (thereby, the output of the bin ■ can be adjusted. The output of lo (102) is connected to the bin ■↓, the inverting transistor (02), the emitter follower transistor CQS)'lx, and then the resistor pa4Jr.
= Input. This resistor (R14) outputs a signal for contour correction.

On the other hand, the video signal of the emitter color of )9 transistor (Ql) passes through a resistor (Rlo) and a delay in (DL2), and then from the emitter of a transistor (Q4) to a resistor (Rlx) t:
Supplied.

At the connection point between the resistor (R115) and the resistor (Rla), the contour correction signal and the original video signal are combined to enhance the contour. This signal is connected to the transistor (Q5)
It is output from the emitter of the transistor (Ql) via (Q6). This output signal is as shown in FIG. 7 (.). Further, the f characteristic of this output signal can be adjusted by the variable resistor port 25, as shown in FIG. 2 (IL) E2.

Next, the speed modulation circuit 2 will be explained. The input video signal is input to the differentiating circuit (g) via an inverting transistor CQIO1) and an emitter follower transistor (Q102). The differential circuit (G) is a resistor (RI
O6) (RI O8):'z Consisting of a capacitor (0102) and a coil (L10 only) This differential circuit (to) extracts only the signal of the contour part from the video signal.

And transistor (Qlox) resistance (R111) (
R11ffi) capacitor (0105): 1il (L1
02) The signal is input to a phase adjustment circuit (A4) constructed as shown in FIG. This circuit (44) adjusts the phase of the differential signal for velocity modulation so that the timing of displaying the video signal on the picture tube surface and the timing of velocity modulation are appropriate. 〇 Phase-adjusted signal is Ia (Icz) rAN614
Depending on the input to the bin ■ of ``, the good signal inputted to the bin ■C is outputted from the bin ■, and the amplitude of this output signal is controlled by the potential applied to the bin ■ζ2. . This output has the characteristics shown in Fig. 2 ω). The output from the bin is the transistor (Ql 04) (
Amplifier circuit G (6
) L: Supplied. The output of the amplifier circuit (40 is output from the output circuit (QloB) consisting of transistors (Q107) (QloB)
7), the auxiliary deflection yoke e1 for speed modulation is supplied.

With the above operation, the contour correction as shown in FIG. 2 (0) can be performed using the variable resistor (37J1m).

Next, the coring effect in which small noise components are removed in the speed modulation circuit 311 will be explained.

4) It is accomplished by l2.

The above differentiation circuit - phase adjustment circuit (44 amplification control circuit r38
The signal for the nine-velocity adjective also includes noise signal components around 1 to 3 MRZ. However, the base of the transistor (010S, l (Q1o6) in the amplifier circuit (.10) is directly connected. Therefore, this transistor (Ql
os) (Q104) base, emitter voltage (Vlm)
For small signals that do not exceed
) ((104) does not operate and C: is not output. As a result, noise signal components whose amplitude is generally smaller than that of the contour signal are removed here.

A second embodiment of the present invention will be shown with reference to FIG. This embodiment is an example of speed modulation control by the brightness adjustment means. In addition, in FIG. 10C2, the same parts as in FIG. 1, FIG. 6, and FIG. 8 are given the same reference numerals.

The device is equipped with a Bedistal clamp circuit, which adjusts the brightness of the screen by adjusting the two-amp level. (52
) is a low-pass filter that removes color signals and audio signals,
(54) is an amplifier, and (56) is a brightness level adjustment circuit, the output level of which is changed by up/down buttons (58), (60), and l2.

(62) is the DO control signal from the brightness level adjustment circuit (56) and the variable resistor 02 for sharpness adjustment.
This is an adder circuit that adds Do control signals from.

Here, if the value of variable resistor CI3 is fixed, the brightness level! ! The output of the I4 adjustment circuit [56] is controlled in conjunction with the pedestal clamp circuit 6G and the speed modulation circuit 39.

1-1#), the pedestal clamp circuit 61 with the brightness level adjustment circuit (56)? : When controlling to brighten both sides, the effect of the speed modulation circuit &I is strongly turned on at 9 o'clock, and when the screen is darkened, the effect is suppressed.

(G) Effects of the Invention In the contour correction circuit according to claim 1 (2), when adjusting contour enhancement, clear enhancement with less rainbow noise can be performed.

In the contour correction circuit of claim 2, when the brightness level is adjusted, appropriate speed modulation can be performed in accordance with the adjustment C2.

[Brief explanation of the drawing]

FIGS. 1 and 2 relate to the first embodiment ζ of the present invention.
The figure is a schematic diagram, and FIG. 2 is a waveform diagram. The third factor is a diagram showing an example of the speed modulation circuit in FIG. 1, FIG. 4 is a diagram showing another example of the speed modulation circuit, FIG. 6 is a diagram showing a speed modulation circuit and a sharpness control circuit, and FIG. The figure is a waveform diagram. FIG. 8 is a diagram showing a conventional example, and FIG. 9 is a waveform diagram thereof. FIG. 10 is a diagram showing a second embodiment of the present invention. Ω・town・picture tube, t, 4e...sharpness control circuit, mouth...
・Variable resistor (sharpness adjustment means), prisoner...speed modulation circuit, ■...auxiliary deflection yoke (deflection yoke), (56)...
- Brightness level adjustment circuit (brightness level adjustment means).

Claims (2)

[Claims] (1) A sharpness control circuit (48) that corrects the contour part of the video signal and outputs it to the picture tube (22), and a sharpness adjustment means (48) that controls the amount of correction in this sharpness control circuit (48). 32), and a yoke (30) that deflects a velocity modulation signal in order to perform contour correction by varying the scanning speed of the electron beam on the contour portion of the video signal.
In the contour correction circuit comprising a speed modulation circuit (29) that outputs an output to The speed modulation circuit (
29) is also controlled, and the sharpness control circuit (
48), this speed modulation circuit (
29) A contour correction circuit characterized in that it also emphasizes contours. (2) a brightness level adjustment means (56) for adjusting the brightness of the image projected on the picture tube (22); and a speed modulation signal for contour correction by varying the scanning speed of the electron beam for the contour portion of the video signal. Deflection yoke (30)
In the contour correction circuit comprising a speed modulation circuit (29) that outputs an output to A contour correction circuit characterized by reducing the size of the contour.