KR920006751Y1 - Color signal compensating circuit of vtr - Google Patents

Abstract

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Description

Color signal compensation circuit in LP mode multifunction of video tape recorder

1 is a skew compensation circuit diagram of an NTSC video tape recorder.

2 is a color signal compensation circuit diagram of a PAL type video tape recorder.

3 is a pattern diagram showing color signals recorded on a video tape in LP mode in SECAM.

4A through 7C are explanatory diagrams showing a carrier frequency of a color signal and a carrier frequency of which skew is compensated for when the LP mode is multifunction in the SECAM method.

8 is a circuit diagram of a video tape recorder equipped with a color signal compensation circuit of the present invention.

9 is a detailed diagram of the color signal compensation circuit of the present invention.

(A)-(d) of FIG. 10, and (a)-(n) of FIG. 11 are waveform diagrams of each part of FIG.

* Explanation of symbols for main parts of the drawings

30: carrier frequency discriminating unit 31, 43: 4.25 MHz filter

32: Integrator 33: Comparator

40 carrier frequency converter 42 balance modulator

44: 4.4 MHz filter 45: analog switch

50: compensation determination unit 51: jump determination unit

52: alternating discrimination unit 53: compensation unit

VR: reference voltage

The present invention compensates the reproduced color signal when the videotape recorder plays the videotape in which the video signal is recorded in the LP (Long Playing) mode. The present invention relates to a color signal compensating circuit for LP mode multifunction of a video tape recorder, and more particularly to a color signal compensating circuit for LP mode multifunction of a video tape recorder suitable for SECAM and MESECAM video tape recorders.

In general, a video tape recorder equipped with the LP mode function generates a skew in which the horizontal synchronizing signal of the video signal collapses when a video tape recorded with the video signal is shifted and reproduced in the LP mode. Compensation circuits should be added. In the NTSC video tape recorder, since the phase and carrier frequency of the color signal do not change before and after 1H (where H is the period of the horizontal synchronization signal), it is not necessary to compensate for the reproduced color signal, but only the horizontal synchronization signal. Compensate for the 0.5 h cycle.

That is, in the NTSC type video tape recorder, as shown in FIG. 1, the composite video signal output from the video reproduction system 1 is delayed by 0.5H to the 0.5H charge coupling device 2, and the skew detection section 3 Detects the occurrence of skew, switches the analog switch 4 to the detection signal of the skew detection unit 3, selects and outputs the composite video signal of the video reproduction system 1 when skew is not generated, When the skew is generated, the skew may be compensated by selectively outputting the 0.5H delayed composite video signal from the 0.5H charge coupling device 2.

In the PAL, SECAM, and SECAM video tape recorders, a 0.5H skew compensation circuit is required in the same way as the NTSC videotape recorder, and the PAL video signal has a phase of +4.43 per 1H due to the characteristics of the video signal. Alternate to MHz and -4.43 MHz, and SECAM video signals require different color signal compensation circuits because the carrier frequencies alternate to 4.25 MHz and 4.4 MHz.

In the PAL type video tape recorder, as shown in FIG. 2, the 4.43 MHz carrier frequency signal (FSC) is multiplied by a double sieve 11 to convert the carrier frequency fsc to 8.86 MHz. The carrier frequency signal and the chroma signal output from the chroma reproducing system 12, that is, the color signal of 4.43, are balanced-modulated by the balance modulator 131 to be converted into a signal of 4.43 ± 8.86 MHz, and then filtered by the -4.43 MHz filter 14. To detect the color signal whose phase is reversed to -4.43 MHz, and the analog switch 15 is switched every 1H according to the control signal CTL, and the 4.43 MHz color signal of the chroma reproducing system 12 and the -4.43 MHz filter 14 It is sufficient to alternately output the color signal whose phase is inverted to -4.43 MHz, which is outputted by), and mix the luminance signal Y with the mixer 16 to compensate for the color signal.

However, in the SECAM type video tape recorder, no suitable color signal compensation circuit has been developed, and the color signal is muted in order to prevent the color of the reproduced picture caused by the distortion of the color signal in the LP mode. mute), there was a problem that the color is not reproduced on the playback screen.

Here, looking at the pattern of the video signal recorded on the videotape in the LP mode of SECAM method, as shown in Fig. 3, the synchronization of the video signal recorded on one track and the video signal recorded on the adjacent track The alignment of the signals is shifted by 0.5H. Therefore, there are four cases in which video signals to be reproduced when the video head jumps to adjacent tracks through high-speed playback or the like are shown in FIGS. 4 to 7 (a).

That is, since the interval between the horizontal synchronization signals of the video signal first reproduced after the video head jumps to the adjacent track is 0.5H, skew occurs, and the carrier frequencies of the color signals alternate between 4.25 MHz and 4.4 MHz. As a result, distortion of the color signal occurs.

Skew generated in this way can be compensated using a skew compensation circuit of the type as shown in FIG. That is, according to the skew detection signal as shown in FIGS. 4 to 7 (b) outputted by the skew detection unit 3, the analog switch 4 is switched at the instant of generating the skew, so that As shown in (c), the skew can be compensated by making the interval of the synchronization signal constant at 1H by selectively outputting the 0.5H delayed video signal instead of the original video signal.

In the case of the skew-compensated video signal, the SECAM scheme requires that the carrier frequency of the color signal be alternated to 4.25 MHz and 4.4 MHz per 1H, as described above. In the case as shown in c), the carrier frequency of the color signal is alternated every 1H, whereas in the case as shown in (c) of FIGS. 5 and 7, the carrier frequency is not alternated during the jump of the track.

Therefore, when the video signal is reproduced as shown in Figs. 5 and 7 (a), the color signal is distorted when the skew of the video signal is corrected as shown in Figs. 4 and 6, respectively (c). If the video signal is reproduced as shown in FIGS. 5 and 7 (a), even if the skew is corrected, the colors can be reproduced on the reproduction screen. As shown in the figure, the carrier frequency of the video signal is not alternating between 4.25 MHz and 4.4 MHz, so that the color signal cannot be clearly reproduced.

Therefore, the purpose of the present invention is to compensate for the carrier frequency of the color signal alternated every 1H according to the carrier frequency without muting the color signal in the LP mode of multi-function in the SECAM type video tape recorder. To provide a color signal compensation circuit to ensure that the image is clearly reproduced.

The color signal compensation circuit of the present invention having such a purpose outputs a discrimination signal by determining whether the carrier frequency of the color signal output from the color signal reproduction system is 4.25 MHz or 4.4 MHz to the carrier frequency discrimination unit. In addition, the carrier frequency of the color signal output from the color signal reproducing system is modulated and filtered by the carrier frequency conversion unit, so that the color signal of 4.25 MHz is converted into a color signal of 4.4 MHz and the color signal of 4.4 MHz is converted into 4.25 MHz. After converting to a color signal, the carrier frequency of the color signal is selected and output so as to be opposite to the carrier frequency of the color signal output from the color reproduction system according to the discrimination signal of the carrier frequency discriminator.

The compensation discrimination unit determines whether the color signal is compensated by using the discrimination signal of the carrier frequency discrimination unit and the synchronization signal of the video signal, and selects and outputs the color signal of the carrier frequency discrimination unit as the color signal needs to be compensated. To compensate.

Hereinafter, the color signal compensation circuit of the present invention will be described in detail with reference to the attached drawings 8 to 11 as follows.

8 is a circuit diagram of a SECAM type video tape recorder having a color signal compensating circuit of the present invention. As shown therein, the luminance signal reproduction system 22 and the color signal reproduction are respectively reproduced from the image signal output from the front end amplifier 21. FIG. The system 23 detects the luminance signal and the color signal, respectively, and the skew detector 24 detects the occurrence of the skew from the detected luminance signal, outputs a detection signal, and outputs the color signal of the color signal reproducing system 23. After compensating with the color signal compensation circuit 25 of the present invention, the mixture is mixed with the luminance signal in the mixer 26, and then delayed by 0.5H with the 0.5H charge coupling device 27, and according to the skew detection signal of the skew detection unit 24, As the switch 28 was switched, the composite video signal of the mixer 26 and the 0.5H delayed composite video signal from the 0.5H charge coupling device 27 were selectively outputted.

9 is a color signal compensation circuit diagram of the present invention, and as shown therein, the color signal compensation circuit 25 of the present invention has a carrier frequency for determining a carrier frequency of a color signal output from the color signal reproducing system 23. According to the discrimination signal of the discriminator 30 and the carrier frequency discriminator 30, the 4.25 MHz and 4.4 MHz carrier frequencies of the color signal of the color signal reproducing system 23 are converted into 4.4 MHz and 4.25 MHz, respectively. The color signal reproducing system 23 and the carrier frequency converting unit determine whether the color signal is compensated by the output signal of the carrier frequency converting unit 40 and the carrier frequency discriminating unit 30 and the horizontal synchronization signal HS. Compensation determination section 50 for selectively outputting the output signal of the (40).

The carrier frequency discriminating unit 30 includes a 4.25 MHz filter 31 for detecting a color signal having a 4.25 MHz carrier frequency from a color signal, an integrator 32 for integrating the output signal of the 4.25 MHz filter 31, and The comparator 33 determines the carrier frequency of the color signal by comparing the output signal of the integrator 32 with the reference voltage V _R.

The carrier frequency converter 40 includes a 150 kHz oscillator 41 for oscillating 150 kHz, a balance modulator 42 for balancing the color signal and the oscillation signal of the 150 kHz oscillator 41, and the balance modulator 42. 4.25 MHz filter 43 and 4.4 MHz filter 44 for detecting color signals of 4.25 MHz and 4.4 MHz carrier frequencies, respectively, from the output signal of the " An analog switch 45 for selectively outputting the output signals of the 4.25 MHz filter 43 and the 4.4 MHz filter 44 alternately opposite the two carrier frequencies of the color signal of (23), and the output of the analog switch 45 And a level adjuster 46 for adjusting the level of the signal.

The compensation determining unit 50 determines whether the video signal jumped to the adjacent track by the synchronization signal HS of the reproduced video signal, the 0.5H monomulti 51A, the 0.5H delayer 51B, and the AND gate AD. ₁ ) a 0.5H delayer for judging whether the carrier frequency has not been altered when jumping to an adjacent track by the output signal of the jump discrimination unit 51 and the jump discrimination unit 51 and the carrier frequency discrimination unit 30 ( 52A), an alternating discrimination unit 52 consisting of an exclusive no-gate EXNR and an AND gate AD ₂ , and output signals LP mode control signals of the jump discriminating unit 51 and the alternating discriminating unit 52 ( LPH) flip-flop (53A, 53B) for selecting an output signal of the color signal reproducing system 23 and the carrier frequency conversion unit 40, such that the carrier frequency of the color signal alternately output in accordance with, the aND gate (AD ₃₎ and analog Compensation section 53 composed of switches 53C.

In the above-described analog switches 45 and 53C, when a high potential is applied to the control terminal, the movable terminal is connected to one fixed terminal a ₁ and a ₂ , and the LP mode control signal LPH is in the LP mode. The high potential is entered.

In the color signal compensation circuit of the present invention, the LP mode control signal LPH is input at a low potential when the video tape is not reproduced in the LP mode, and thus the reset terminal of the flip-flops 53A and 53B. Since it is applied to the flip-flop 53A (53B) is reset to output a low potential to the output terminal (Q ₁ ) (Q ₂ ).

Therefore, the AND gate AD ₃ outputs a low potential, and the movable terminal of the analog switch 53C is connected to the other fixed terminal b ₂ , so that the color signal output from the color signal reproducing system 23 remains the analog switch ( 53C) to mixer 26.

When the video tape is played back in the LP mode, since the high potential is inputted as the LP mode control signal LPH, the flip-flops 53A and 53B are reset.

In this state, when the color signal reproducing system 23 outputs a color signal in which the carrier frequency alternates at 4.25 MHz and 4.4 MHz per 1H, as shown in Fig. 10A, the carrier frequency discriminating unit is selected from among the color signals. The 4.25 MHz filter 31 of (30) detects the color signal of the 4.25 MHz carrier frequency and outputs it as shown in Fig. 10B. The integrator 32 shows as shown in Fig. 10C. Since it is integrated and applied to the non-inverting input terminal (+) of the comparator 33, the comparator 33 compares the output signal of the integrator 32 with the reference voltage V _R , as shown in FIG. Likewise, when the carrier frequency is 4.25 MHz, the high potential is output, and when the carrier frequency is 4.4 MHz, the low potential is output.

Then, the 150 Hz oscillator 41 oscillates and outputs an 105 Hz oscillation signal, and the 150 Hz oscillation signal is input to the parallel modulator 42 together with the color signal output from the color signal reproducing system 23 to perform parallel modulation. do. Therefore, when the carrier frequency of the color signal is 4.25 MHz, the parallel modulator 42 outputs the color signal whose carrier frequency is converted to 4.25 ± 0.15 MHz, that is, 4.1 MHz and 4.4 MHz, so that the color signal of the 4.4 MHz carrier frequency is 4.4 MHz. When the carrier frequency is 4.4 MHz, the balanced modulator 42 converts the carrier frequency to 4.4 ± 0.15 MHz, that is, 4.25 MHz through the filter 44 to the fixed terminal a ₁ of the analog switch 45. The color signal is output and the color signal of the 4.25 MHz carrier frequency is applied to the other fixed terminal b1 of the analog switch 45 through the 4.25 MHz filter 43.

At this time, when the carrier frequency of the color signal output from the color signal reproduction system 23 is 4.25 MHz, the comparator 33 outputs a high potential as described above, and the analog switch 45 has a carrier frequency of 4.25 MHz as 4.4. The output signal of the 4.4 MHz filter 44 converted to the carrier frequency of MHz is selectively output.

When the carrier frequency of the color signal output from the color signal reproducing system 23 is 4.4 MHz, the comparator 33 raises the low potential so that the movable terminal of the analog switch 45 is connected to the other fixed terminal b ₁ . Since it is connected, the analog switch 45 selectively outputs the output signal of the 4.25 MHz filter 43 in which the carrier frequency of 4.4 MHz is converted into 4.25 MHz. In this way, the color signal selected and output by the analog switch 45 is applied to one fixed terminal a ₂ of the analog switch 53C by adjusting the level of the level controller 46.

That is, the carrier frequency converter 40 exchanges two carrier frequencies of the color signal output by the color signal reproducing system 23, and outputs the same level.

Also, the horizontal synchronizing signal HS of the reproduced video signal is input as shown in Fig. 11A, and the 0.5H monomulti 51A is 0.5H wide as shown in Fig. 11B. The output pulse signal is applied to the AND gate AD ₁ and is delayed from the 0.5H retarder 51B to the AND gate AD ₁ as shown in FIG. ₁ ) outputs a pulse signal whenever the video head jumps to an adjacent track and the width of the reproduced video signal is 0.5H, as shown in (d) of FIG. 11, and according to the output pulse signal, the flip-flop 53A It is toggled so that its signal is inverted as shown in (e) of FIG. 11 to its output terminal Q ₁ .

Then, when the carrier frequency of the reproduced color signal is as shown in (f) of FIG. 11, the discriminating signal shown in (g) of FIG. The carrier frequency of the reproduced color signal is applied to the gate EXNR and applied to the exclusive noah gate EXNR after being delayed by 0.5H as shown in (h) of FIG. 11 in the 0.5H delay unit 52A. Is shown in (j) of FIG. 11, the discriminator signal shown in (k) of FIG. 11 output from the comparator 33 is applied to the Exact Noar Gate EXNR and a 0.5H delayer ( As shown in (l) of FIG. 11 at 52A), a delay of 0.5H is applied to the Exclusive Noahgate (EXNR), so in both cases, the Exclusive Noagate (EXNR) is shown in (m) of FIG. The pulse signal is output as shown.

Therefore, when it is necessary to convert the carrier frequency when jumping to the adjacent track, the AND gate AD ₂ outputs a pulse signal as shown in FIG. 11 (m), and the flip-flop 53B is toggled to As shown in (n), since the high potential is output, the AND gate AD ₃ outputs the high potential, and the movable terminal of the analog switch 53C is connected to one fixed terminal a ₂ so that two carrier frequencies Outputs the color signals that are interchanged with each other.

That is, when it is not necessary to convert the carrier frequency when jumping to the adjacent track, the color signal of the color signal reproducing system 23 is selected, and when the carrier frequency is to be converted, the carrier frequency conversion unit 40 has two carrier frequencies. Selectively output the color signals converted from each other.

As described in detail above, the present invention has the effect of clearly reproducing the color on the playback screen because the SECAM type video tape recorder outputs the carrier frequency of the color signal alternately every 1H when the video tape is shifted and reproduced in the LP mode. .

Claims (4)

In the luminance signal reproducing system 22 for reproducing and detecting the luminance signal from the video signal output from the front end amplifier 11, the color signal reproducing system 23 for reproducing and detecting the color signal, and in the luminance signal reproducing system 22 A skew detector 24 for detecting and outputting the occurrence of skew from the detected luminance signal, and a mixer for mixing the luminance signal in the luminance signal reproducing system 22 and the color signal in the color signal reproducing system 23 ( 26), a 0.5H charge coupling device 27 for delaying the mixed signal by the mixer 26 by 0.5H, and a video signal or 0.5H delay complex that is switched while being switched according to the detection signal of the skew detector 24. In a video tape recorder composed of an analog switch 28 for outputting a video signal, a color signal compensating circuit 25 for compensating color signals reproduced between the color signal reproducing system 23 and the mixer 26 is provided. The color signal compensation circuit 25 is phased 4.25 MHz and 4.4 MHz of the reproduced color signal according to the carrier frequency discriminating unit 30 for discriminating the carrier frequency of the color signal reproduced by the color signal reproducing system 23 and the discriminating signal of the carrier frequency discriminating unit 30. The carrier frequency converting unit 40 which alternately outputs the carrier frequency to 4.4 MHz and 4.25 MHz, and the synchronization signal of the carrier frequency discriminating unit 40 and the synchronizing signal of the reproduced video signal determine whether or not to compensate the color signal. Compensation determination unit 50 for selecting and outputting the reproduced color signal and the output signal of the carrier frequency conversion unit Color signal compensation circuit for the multi-function mode of the video tape recorder The integrator according to claim 1, wherein the carrier frequency discriminating unit (30) integrates a 4.25 MHz filter (31) for detecting a color signal of one carrier frequency in the reproduction color signal and an output signal of the 4.25 MHz filter (31). And a comparator (33) for discriminating the carrier frequency by comparing the output signal of the integrator (32) with a reference voltage. 2. The carrier frequency converting section (40) according to claim 1, wherein the carrier frequency converting section (40) has a balance modulator (42) for balancing modulating a reproduced color signal and an oscillation signal of 150 Hz, and the output signal of the balance modulator (42), 4.25 MHz filter 43 and 4.4 MHz filter 44 for detecting the color signal of the carrier frequency, and the 4.25 MHz filter 43 and 4.4 MHz filter 40 so that the carrier frequency alternates with the carrier frequency of the reproduction color signal. Color of the video tape recorder of the video tape recorder, comprising: an analog switch 45 for selectively outputting an output signal of Signal compensation circuit. The apparatus of claim 1, wherein the compensation discrimination unit (30) includes a jump determining unit (51) for judging whether a jump is made to an adjacent track with a synchronization signal of a reproduced video signal, and the jump discriminating unit (51) and carrier frequency when jumping to an adjacent track. The alternating discrimination unit 52 for determining whether the carrier frequency is not altered by the discriminating signal of the discriminating unit 30, the output signal paths of the jump discriminating unit 51 and the alternating discriminating unit 52, and the LP mode control signal. Color signal compensation circuit in the LP mode multifunction of the video tape recorder, characterized in that it comprises a compensator 53 for selecting the reproduction color signal and the output signal of the carrier frequency converter 40 so that the carrier frequency of the color signal is alternately .