DE4012677A1 - VIDEO SIGNAL FORMAT CONVERTER CIRCUIT - Google Patents

Abstract

To convert an NTSC video signal a into one b with a PAL type sub-carrier, the output r1 of a clock 44 at four times the PAL sub-carrier frequency fsc is passed to a divide by four frequency divider 45 and logic 46 - 48 to provide three signals A1 - C1 each at fsc and with relative phases of -45 DEG , 0 DEG , and +45 DEG . The latter or a zero signal D1 are selected at SW1 for mixing at 42 with the NTSC sub-carrier r2, according to PAL phase (B1 or D1) in the active line period, or colour burst phase (A1 or C1), and the resulting signal c is mixed at 4 with the separated chrominance component of the NTSC signal a. In a modification (Fig 13) both sum and difference signals from the mixer 42 are used. The arrangement is such that only colour signals on alternate lines are converted, when signal B1 is provided, and the missing lines are produced from the converted lines. A variable gain circuit 50 enables the reduced chrominance resulting from such a process to be corrected automatically; the burst amplitude is reduced so that a subsequent variable gain circuit in an ACC detector (22, Fig 3) increases the level of the whole signal to that of a normal (unconverted) signal. <IMAGE>

Description

The invention relates to a video signal format converter scarf tung.

For color video signals in NTSC video format (hereinafter referred to as NTSC color video signal), the number of scan lines is 525 at a field frequency of 60 Hz and a subcarrier frequency of 3.58 MHz. On the other hand, in the color video signal of the PAL video format (hereinafter referred to as PAL color video signal), the number of scanning lines 625 at a field frequency of 50 Hz and a subcarrier frequency of 4.43 MHz.

There is a need to perform the reproduction of images from a disc on which the NTSC color video signal is recorded also with a PAL video display system such as a television for reproducing images from the PAL color video signal. In order to meet this need, it was proposed to incorporate a signal format conversion circuit according to FIG. 1 for converting the NTSC color video signal into a pseudo PAL color video signal according to FIG. 1 in a video disc player.

In Fig. 1, an NTSC color video signal a obtained from a plate is supplied via an input terminal IN to a subtractor 2 and an adder 3 . The NTSC color video signal a is also supplied to a 1H delay circuit 1 in which the signal a is delayed by 1H (one horizontal scan length), and the delayed NTSC color video signal a is supplied to the subtractor 2 and the adder 3 . In the subtractor 2 , a luminance signal component is deleted, so that only one chrominance signal component is transmitted. Conversely, the chrominance signal component is deleted in the adder 3 , so that only the luminance signal component is passed through. The chrominance signal component output from the subtractor 2 is fed to a multiplier 4 , in which the color signal component is multiplied by the output signal of an oscillator 5 .

The oscillation frequency of the oscillator 5 is set to 854 kHz, that is the difference between the frequency of the color subcarrier signal in the PAL color video signal (4.43 MHz) and the frequency of the color subcarrier signal in the NTSC color video signal (3.58 MHz). So in the multiplier 4 he will receive a signal which is obtained by converting the frequency of the chrominance signal component from 3.58 MHz to 4.43 MHz. The color signal component of 4.43 MHz, which is output from the multiplier 4 , phase shifters 7 and 8 and a sta tionary contact B _{1 of} a switch SW ₁ via a bandpass filter 6 , whose pass band center frequency is 4.43 MHz.

The phase shifter 7 is designed so that it carries out a phase shift of the input signal by + 45 °. The Pha senschieber 8 performs a phase shift of the input signal from -45 °. The output signals of the phase shifters 7 and 8 are fed to the stationary contacts A ₁ and C _{1 of} the switch SW ₁ , respectively. A stationary contact D _{1 of} the switch SW ₁ is grounded.

A control circuit 9 for the switch is provided, and its output signal is applied to a control input terminal of the switch SW ₁ . The switch SW ₁ is designed so that, depending on the incoming control signal, the movable contact E _{1 is in} contact with one of the stationary contacts A ₁ to D ₁ . The control circuit 9 for the switch is designed so that it detects a time length T ₁ in the horizontal scanning period in which the color burst is present and a time length T ₂ outside of the horizontal sync signal in the NTSC color video signal a Length of time T ₁ in which the video information signal is present. The circuit 9 generates as a switching control signal a signal for connecting the movable contact E ₁ alternately with the stationary contacts A ₁ or C ₁ with intervals of 1 H during the time length T ₁ and for connecting the movable contact E ₁ alternately with the stationary contacts B ₁ and D ₁ with a period of 1 H during the time length T ₂ .

The signal picked up at the movable contact E _{1 of} the switch SW ₁ is fed to an adder 10 , in which it is summed with the luminance signal component from the adder 3 , so that a color video signal is formed. The output signal of this adder 10 is applied to the output terminal OUT and leads to a (not shown) PAL video display system.

In the circuit described, when the NTSC color video signal a according to FIG. 2A is applied to the input terminal IN, a signal obtained by 45 ° phase shift of the converted to the frequency of 4.43 MHz chrominance signal component and a signal by -45 ° -Phase shift of the same chrominance signal received signal alternated with intervals of 1H at the movable contact E _{1 of} the switch SW _{1 derived} during the time T ₁ . On the other hand, during the time T ₂ , the chrominance signal component and a signal with zero amplitude are derived alternately at the movable contact E ₁ . Therefore, the chrominance signal component d output from the movable contact E _{1 of} the switch SW ₁ becomes a signal as shown in Fig. 2B. This chrominance signal component d is fed to the adder 10 where it is combined with the luminance signal component, and the output of the adder 10 then becomes the color video signal b as shown in Fig. 2C.

When this color video signal b (not shown) PAL video reproducing system is supplied, the signal b to a demodulation circuit according to Fig. 3 applied. In Fig. 3, the color video signal b is applied to a Y / C isolation circuit 20 and a sync isolation circuit 21 . In the Y / C separation circuit 20 , the luminance signal component and the chrominance signal component are separated from the color video signal b , and the luminance signal component is supplied to an image tube drive circuit (not shown) for driving a picture tube. On the other hand, the chrominance signal is applied to a burst phase discriminator circuit 23 , a 1H delay line 24 , a polarity reversal circuit 25 and an adder 26 via an ACC circuit (automatic color saturation control) 22 . The ACC circuit 22 contains an amplifier 22 a with a variable gain for amplifying the chrominance signal component, a burst gate circuit 22 b for separating a color burst signal from the chrominance signal component, an ACC detector circuit 22 c for generating an ACC voltage corresponding to the level of the Burst gate circuit 22 b separated color burst signal and supplying the voltage as a gain control signal to the amplifier 22 with variable gain. With these circles, the ACC circuit 22 adjusts the gain of the amplifier 22 a so that the level of the color burst signal is kept constant.

In the burst phase discriminator circuit 23 , the color burst signal is separated from the chrominance signal component and supplied to a subcarrier generator circuit 33 , and a reset signal is generated each time the phase of the color burst signal is equal to a certain phase. The reset signal is applied to a T flip-flop 34 . At a trigger input of the T flip-flop 34 , the horizontal sync signal separated from the color video signal by the sync separating circuit 21 is supplied such that inversion of the T flip-flop occurs at 1H intervals.

In the 1H delay line 24 , the chrominance signal component is delayed by 1H, and the delayed signal is supplied to the adders 26 and 27 .

In the adder 26 , the chrominance signal and the signal obtained by delaying the chrominance signal by 1 H are added together. The adder 26 is designed so that the R / Y component in the PAL color video signal with the phase alternation is canceled at intervals of 1H and only the B / Y components are generated. In the color video signal b , however, the chrominance signal component only exists during the times T ₂ , which occur every second 1H time length. Therefore, the chrominance signal component which exists time-length 1H in the period T ₂ in each second is outputted from the adder 26 also in the time T ₂ of the next 1 H period length, so that the chrominance signal component is output in every 1H period length.

In the adder 27 , a reverse phase component of the chrominance signal component and the signal obtained by delaying the chrominance signal component by 1H are added together. The adder 27 is designed so that the B / Y component in the PAL color video signal is canceled and only the phase-inverted R / Y component is output in every 1H time length. However, as with the adder 26 , the chrominance signal component is output from the adder 27 every 1H period.

Output signals of adders 26 and 27 are supplied to synchronous detectors 28 and 29, respectively. A color subcarrier signal is generated by a subcarrier generator circuit 33 and phase-shifted by 90 ° by a phase shifter 35 . The phase-shifted subcarrier signal is fed to the synchronous detector 28 . The generated by the subcarrier circuit 33 te color subcarrier signal and a by a 180 ° -Phasenver shift of the color subcarrier signal in the phase shifter 35 he signal is alternately via a switch 36 with an alternating rate of 1H leads to the synchronous detector 29 . By means of the synchronous detectors 28 and 29 , the B / Y signal and the R / Y signal are demodulated and supplied to the picture tube drive circuit (not shown) via low pass filters 31 and 32 with a cutoff frequency of 1.3 MHz, so that the color image is reproduced.

As previously specifically described, the conventional signal format conversion circuit 1 7 and 8, coils, capacitors, resistors contains according to Fig., The phase shifters, etc., and is designed in a way that it processes the incoming signal and performs the phase shift in analog form. For this reason, due to the changes in the values of each circuit element, an accurate phase shift cannot be obtained, and the operation of this circuit is very easily affected by the temperature characteristics of each circuit element. For this reason, a high-quality color image cannot always be obtained.

To overcome this problem, the present inventor development, and it is an object of this invention to achieve a Signal format converter circuit for processing a video i gnals to create, where the video signal format without analog ge phase shift is converted so that at any time Color image with high quality is achievable.

In the signal format converter circuit according to the invention generates a first reference signal with a frequency that four times the frequency of the color subcarrier in the PAL System is, there are first to third phase shift signals generates on the basis of the first reference signal and an output signal of a reducing device for reducing the frequency of the first signal with a factor of 4, the first to  third phase shift signal have the same frequency like the output of the reducer and the series are out of phase by a length of time that is half Period of the first reference signal corresponds, and a Signal by changing the frequency and phase of the chro minance signal and the color burst signal of an NTSC color video signals are obtained by using the first to third Phase shift signal, and this is called a PAL Videosi gnal output.

The invention is described below with reference to the drawing exemplified in more detail; in this shows:

Fig. 1 is a block diagram of a conventional signal format conversion circuit;

Figs. 2A to 2C are waveform diagrams of parts of the TIC shown in FIG. 1 signals occur,

Figure 3 is a block diagram of the demodulator circuit used in the PAL system;

Fig. 4 is a block diagram of an embodiment of a signal format converter circuit according to the invention;

Fig. 5A to 5D, 6A to 6I, 7A to 7D respectively Wellenformdia programs the function of parts of the circuit of Fig. 4,

Fig. 8 is a diagram of part of the reproduced image;

FIG. 9A to 9C are waveform diagrams of the function of tarry approximately circle 51;

FIG. 10A and 10B, 11A and 11B, 12A to 12C are vector diagrams of the chrominance signal component;

Fig. 13 is a block diagram of another embodiment of the invention;

FIG. 14A to 14I are waveform diagrams of the function of each part of the circuit of Fig. 13; and

FIG. 15A and 15B, according to Fig. 15 joined together, a block diagram of another embodiment of the present the invention.

In Fig. 4, the 1H delay circuit 1 , the subtractor 2 , the adder 3 , the multiplier 4 and the bandpass filter 6 are connected to each other in the same manner as in the circuit of Fig. 1, but a bandpass filter 41 is provided in this embodiment whose output signal is fed to the multiplier 4 . The bandpass filter 41 has a center frequency of 854 kHz, and an output signal of a multiplier 42 is present at the bandpass filter 41 . The multiplier 42 receives an output signal of a digital phase shifter 40 and an output signal of an oscillator 43 . The oscillator 43 is designed so that it generates a reference signal r ₂ , the frequency of which is equal to the frequency of the color subcarrier in the NTSC format video signal.

The digital phase shifter 40 receives an output signal from an oscillator 44 . The oscillator 44 is designed so that it generates a reference signal r ₁ , the frequency of which is four times the frequency of the color subcarrier signal in the PAL format video signal. In the digital phase shifter 40 , the frequency of the reference signal r ₁ at 45 is divided by four, directly to a clock input terminal CK of a D flip-flop 47 and via an inverter 48 to a clock input terminal CK of a D flip-flop 46 . The output signal of the reducer 45 is applied to the D input terminal of the D flip-flop 46 and also fed to the stationary contact C _{1 of} a switch SW ₁ . The -output signal of the D flip-flop 46 is fed to a D input terminal of the D flip-flop 47 and also to a stationary contact B _{1 of} the switch SW ₁ . The output signal of the D flip-flop 47 is supplied to a stationary contact A _{1 of} the switch SW ₁ , and a stationary contact D _{1 of} the switch SW ₁ is grounded. The output signal of the changeover control circuit 9 is applied to a changeover control terminal of the changeover switch SW ₁ , as in the circuit in FIG. 1.

The output from the bandpass filter 6 chrominance signal components te is applied via a gain control 50 to an input terminal of the adder 10 . The gain controller 50 consists of a means for detecting the length of time T ₁ in which the color burst signal is present and for generating a gain decrease control signal, and an amplifier with a variable gain, the gain of which is reduced as a function of the gain decrease control signal. The luminance signal component, which is the output signal of the adder 3, is applied to the other input terminal of the adder 10 , delayed by a time length T _D by means of a delay circuit 51 . The chrominance signal component and the luminance signal component are combined by summation in the adder 10 to provide a color video signal. The delay time T _D in the delay circuit 51 is set to a value which is equal to a summation ( 250 ns + Δ D) from a value corresponding to half the difference between 1 H in the NTSC system and 1H in the PAL system and a delay time Δ D in the bandpass filter 6 .

The output signal of the adder 10 is applied to an amplitude suppressor circuit 52 and a vertical sync separator circuit 53 . In the vertical sync separator circuit 53 , the vertical sync signal is separated from the color video signal output from the adder 10 , and the vertical sync signal is applied to a monostable multivibrator (MMV) 54 . The MMV 54 is designed so that it is triggered by a rising edge of the output signal of the vertical sync separating circuit 53 and generates a pulse signal that is present during a time T ₃ , starting from an extinction time of the vertical sync signal and a completion time of the vertical blanking time. This output pulse signal of the MMV 54 is supplied to the amplitude limiter circuit 52 . The amplitude limiter circuit 52 is designed such that it limits the instantaneous level of an applied signal to values below a level V _A which is a little higher than the base level, for example in dependence on the output pulse signal of the MMV 54 . An output signal of the amplitude limiter circuit 54 is supplied to an output terminal OUT.

In the structure described, the following operations are carried out. According to FIG. 5A, the reference output signal r ₁ at four times the frequency of the color subcarrier of the PAL-format video signal from the oscillator 44 from the oscillator 44. The output signal of the reducer 45 , which divides this reference signal R ₁ by four, is shown in Fig. 5D. This output signal of the reducer 45 is fed to the D input terminal of the D flip-flop 46 as a phase shift signal fsc ₃ with the same frequency as that of the color subcarrier signal in the PAL system, and also a stationary contact C _{1 of} the switch SW ₁ .

Since the reference signal r _{1 is applied} to the clock input terminal of the D flip-flop 46 via the inverter 48 , the phase shift signal fsc ₃ in the D flip-flop 46 is held by the falling edge of the reference signal r ₁ , and the Q output signal of the D -Flip-flop 46 becomes equal to a signal which is obtained by phase-advancing the phase-shift signal fsc ₃ by 45 ° according to FIG. 5C. The Q output signal of the D flip-flop is applied to the D input terminal of the D flip-flop 47 as a phase shift signal fsc ₂ and also to the stationary contact B _{1 of} the switch SW ₁ .

Since the reference signal r _{1 is} fed directly to the clock input terminal of the D flip-flop 47 , the phase shift signal fsc ₂ in the D flip-flop is held by the rising edge of the reference signal r ₁ and the output signal of the D flip-flop becomes one Signal obtained by phase advancing the phase shift signal fsc ₂ by 45 ° as shown in FIG. 5B. This Q output signal of the D flip-flop 47 is applied to the stationary contact A _{1 of} the switch SW ₁ as a phase shift signal fsc ₁ .

Assuming that an NTSC color video signal a is applied to the input terminal IN according to FIG. 6A, the movable contact E _{1 of} the switch SW ₁ comes in sequence with the stationary contacts A ₁ , C ₁ , D ₁ and B. ₁ in contact as shown in Figs. 6B to 6E. In particular, in the period T ₁ in which the color burst signal is present, the movable contact E _{1 is} alternately connected at intervals 1 H to the stationary contacts A ₁ and C ₁ . In the period T ₂ in which the video information signal is present, the movable contact E _{1 is} alternately connected to the stationary contacts B ₁ and D ₁ with the period 1 H. Thus, the phase shifter signals fsc ₁ and fsc ₃ alternately on the movable contact E ₁ with time intervals 1H during the period T ₁ , and the phase shifter signal fsc ₂ and the Erdpegelsi signal are at the rate 1 H on the movable contact E ₁ during the Period T ₂ derived. Since the signal derived at the movable contact E ₁ is applied to the multiplier 42 and multiplied by the reference signal r ₂ with a frequency of 3.58 MHz, a signal with the frequency of 854 kHz, ie the difference between the frequencies of the phase shifter signals fsc ₁ to fsc ₃ and the frequency of the reference signal r ₂ generated. As shown in Fig. 6F, this signal is a converter signal c , whose phase during the period T ₁ with intervals 1 H between -45 ° and + 45 °, and the amplitude during the period T ₂ at every two 1H- Period goes to zero.

The converter signal c at 854 kHz is fed to the multiplier 4 through the bandpass filter 41 . A color signal component d according to FIG. 6G is formed in the multiplier 4 . The color signal component d has a frequency of 4.43 MHz, which differs from the chrominance signal component in the NTSC system by 854 kHz, and its phase change between + 45 ° and -45 ° occurs with the period of 1H and the amplitude of its video information decreases to zero every second 1H period. The chrominance signal component d is applied to a gain control circuit 50 through the band-pass filter 6 so that the color burst signal level drops by a predetermined amount. In this way, a chrominance signal is generated by the gain control circuit 50 . The chrominance signal e output from the gain control circuit 50 , as shown in FIG. 6H, is supplied to the adder 10 , and in this the chrominance signal is combined by addition with the luminance signal component delayed in the delay circuit 51 by the time length T _D. A color video signal b according to FIG. 6I is generated in this way.

The color video signal b is supplied to the amplitude limiter circuit 52 and a vertical sync separator circuit 53 . A vertical sync signal v according to FIG. 7b is thus generated, which exists during a vertical sync time length T _V in the vertical blanking time T _{E of} the color video signal B according to FIG. 7A, and by the vertical sync signal Isolation circuit 53 issued. When the vertical sync signal v is supplied to the MMV 54 , the MMV 54 is triggered by the rising edge of the vertical sync signal v and outputs a pulse p with a time length T _Q in FIG. 7C. When the pulse p of the amplitude limit circuit 52 is supplied, an amplitude limit is carried out so that the instantaneous level of the color video signal b is kept below the level V _A which is slightly larger than the base level. As a result, as shown in FIG. 7D, the code signal used in certain lines within the vertical retrace time length T _{E of} the color video signal essentially disappears. The color video signal b output by the amplitude limiter circuit 51 is supplied to the output terminal OUT and in turn to a (not shown) PAL video display system. This prevents the generation of incompatible images formed by changes in the luminance level due to the presence of the code signal.

The frequency of the color video signal b derived at the output terminal OUT is identical to the horizontal sync frequency in the NTSC system. Therefore, when the color video signal b is supplied to a PAL video display system (not shown), a color error is generated because the delay time of the 1H delay line 24 in the demodulator of Fig. 3 is the 1H time length ( 64 µs) of the PAL color video signal is set. In particular, during the time when the amplitude of the chrominance signal component of the color video signal b is zero, only the chrominance signal component, which was present 1H before and is supplied to the adders 26 and 27 via the 1H delay line, is fed to the synchronous detectors 28 and 29 . During the time when the amplitude of the chrominance signal component is not equal to zero, only the chrominance signal component which is fed directly to the adders 26 and 27 is supplied to the synchronous detectors 28 and 29 for reproducing color images. Therefore, as shown in Fig. 8, an error w of 500 ns corresponding to the difference between 1H of the PAL color video signal and 1H of the NTSC color video signal is generated between the color signals of two adjacent scan lines L _n to L _{n + 3} . However, as shown in FIG. 9A, the color video signal b consists of the chrominance signal component according to FIG. 9C and the luminance signal component according to FIG. 9B, delayed by the delay circuit 51 by the time length T _d (≈ 250 ns) with respect to the chrominance signal component. Therefore, contour lines formed by the luminescence signal component in adjacent scan lines L _n to L _{n + 3 will} sit in the middle of the error width of the color signals, as shown by the dash-dotted line in FIG. 8. This makes the color error less noticeable.

The amplitude of the chrominance signal component of the color video signal b is reduced to zero alternately every second 1H period during the time length T ₂ . Therefore, when the color video signal b is supplied to the video display system (not shown), the amplitude of one of the two input signals of the adders 26 or 27 in the demodulator of Fig. 3 of the video display system, that is, the amplitude of either the chrominance signal or by delaying the chrominance signal by 1H received signal reduced to zero. Therefore, the level of the chrominance signal component output from the adders 26 and 27 becomes lower than when the regular PAL color video signal is supplied with a chrominance signal component whose amplitude is not reduced to zero.

The chrominance signal component of the regular PAL color video signal can be represented by a vector diagram according to FIG. 10A. Fig. 10A shows the chrominance signal component f ₁ and the color burst signal g ₁ , which accompanies the chrominance signal component f ₁ in the respective second consecutive H-time clearing. The R / Y component of the chrominance signal component f ₁ is alternately inverted in phase with respect to a B / Y axis with a periodic change of 1H.

In this state, the color burst signal g ₁ is output with a phase change of ± 135 ° corresponding to the phase change of the R / Y signal components. In the regular PAL color video signal, the synchronous detection of a chrominance signal component f _{2 shown} in FIG. 10B is effected, which is obtained by summing a chrominance signal component f ₁ with a signal obtained by inverting only the R / Y component of the chrominance signal f _{1 is obtained} from 1H beforehand.

If we turn to the color signal b , the chrominance signal component can be represented by a vector diagram according to FIG. 11A. In Fig. 11A is also a chrominance signal component f ₁ , in two consecutive 1H time lengths and a color burst signal g ₁ ', which accompanies the chrominance signal component f ₁ ', in the same manner as in Fig. 10A Darge. The amplitude of the chrominance signal component f ₁ 'drops to zero in every second 1H time length, while the color burst signal g ₁ ' is output in the same way as the color burst signal of the regular PAL color video signal. Because of the color video signal b, the chrominance signal component f ₁ 'as it is, the synchronous Chromi nanzsignalkomponent f ₂ ', and the level of the synchronous detectors 28 and 29 supplied chrominance signal component becomes lower than the level at the regular PAL color video signal is obtained.

The level of the color burst signal g ₁ 'of the color video signal b is, however, kept small by the amplitude limiter circuit 52 according to FIG. 12A. Therefore, by the ACC circuit 22 in the video playback signal, the gain of the amplifier for amplifying the color burst signal g ₁ 'and the Chromi nanzsignalkomponent f ₁ ' is increased until the level of the color burst level g ₁ 'reaches a predetermined level, as in FIG. 12B. Thus, the level of the color signal component f ₂ to be detected synchronously is increased in the manner shown in FIG. 12C and a reduction in the color intensity is avoided.

Fig. 13 is a block diagram showing another embodiment according to the Invention. In this embodiment, the 1H delay circuit 1 , the subtractor 2 , the adder 3 , the multiplier 4 , the bandpass filter 6 , the delay circuit 51 , the amplitude limiter circuit 52 , the vertical sync separator circuit 53 and the MMV 54 are in the same connected to each other as in the circuit of FIG. 4, but in this embodiment, the output signal of the bandpass filter 6 is supplied directly to the adder 10, and the surfaces on a bewegli contact C ₂ of a switch SW ₂ derived signal is supplied to the multiplier 4. A generator circuit 61 for a changeover control signal is provided, and its output signal is supplied to a control input terminal of the changeover switch SW ₂ . The switch SW ₂ is designed so that accordingly the signal applied to the control terminal of the movable contact C _{2 be} connected to a stationary contact A ₂ or B ₂ . The generator circuit 61 for the Umschaltsteuer signal is designed so that it detects, for example, by the Ho rizontal sync signal of the NTSC color video signal, the time length T ₁ in which the color burst signal is present, and the time length T ₂ in which the video information signal is present at every horizontal scan length. Accordingly, these detected times, the circuit 61 generates a control signal for the movable contact C ₂ so that it is connected to the stationary contact B ₂ during the length of time T ₁ and alternately at a periodic rate of 1H with the during the time length T ₂ Contacts A ₂ and B ₂ .

The stationary contact A _{2 of} the switch SW ₂ is supplied with an output signal from a bandpass filter 62 . The center frequency of the pass band of the bandpass filter 62 is set to 8.01 MHz. The stationary contact B _{2 of} the switch SW ₂ , an output signal of a bandpass filter 41 is supplied, and the output signal of the multiplier 42 is applied to the bandpass filters 41 and 62 . The output signals of the digital phase shifter 40 and the oscillator 43 are fed to the multiplier 42 as in the circuit in FIG. 4.

The digital phase shifter 40 is designed as in the circuit in Fig. 4, however, the He designed in this embodiment zeugerkreis 9 for the switching control signal in the digital Pha shifters and 40 so that a switching control signal is generated so that the movable contact E _{1 of} the switch SW ₁ with the stationary contacts A ₁ and C ₁ alternately with the period 1 H during the length of time T ₁ comes in contact and during the length of time T ₂ with the stationary contact B ₁ .

With this structure described, the NTSC color video signal a according to FIG. 14A of the input terminal IN is applied, the movable contact E _{1 of} the switch SW ₁ comes in succession with the stationary contacts A ₁ , C ₁ and B ₁ in connection, as in FIG FIG. 14B to 14D, under the control of the generation circuit 9 for the switching control signal. In particular, during the period T ₁ when the color burst signal is present, the movable contact E ₁ with the period 1 H alternates with the stationary contacts A ₁ and C ₁ and during the period T ₂ when the video information signal is present with the stationary contact B ₁ verbun the. Thus, the phase shifter signals fsc ₁ and fsc _{3 are} alternately removed from the movable contact E ₁ with the period 1 H during the period T ₁ and the phase shift signal fsc ₂ is removed from the movable contact E ₁ during the period T ₂ . Since the signal obtained at the movable contact E _{1 is} fed to the multiplier 42 and multiplied by the reference signal r ₂ of 3.58 MHz, the multiplier 42 generates two signals with frequencies of 854 kHz and 8.01 MHz, which is the difference and the sum of the frequencies of the phase signals fsc ₁ to fsc ₃ and the reference signal R ₂ corresponds, the phases of which alternate in size + 45 ° and -45 ° with the period 1 H during the period T ₁ , while in the period T ₂ no phase change occurs.

The signal with the frequency of 854 kHz is fed to the stationary contact B _{2 of} the switch SW ₂ through the bandpass filter 41 and the signal with the frequency of 8.01 MHz is fed to the stationary contact A _{2 of} the switch SW ₂ through the bandpass filter 62 .

By the switching control signal from the circuit 61 , the movable contact C _{2 of} the switch SW _{2 is} alternately connected to the stationary contacts B ₂ and A ₂ according to FIGS . 14D and 14E. Accordingly, the 854 kHz signal is derived at movable contact C ₂ during period T ₁ and the two 854 kHz and 8.01 MHz signals are derived alternately with the 1H period during period T ₂ at movable contact C ₂ , so that a converter signal c 'is generated after 14G. The converter signal c 'is fed to the multiplier 4 , so that the chrominance signal component accordingly the NTSC system is multiplied by the converter signal c ' in the multiplier 4 .

Assuming that an input signal of the multiplier 4 is expressed by cos α, while the other may be expressed by cos β, the output signal of the Mul tiplizierers 4 is expressed by the following equation

cos α cos β = 1/2 {cos (α + β) + cos (α - β)} (1)

Since one of the input signals of the multiplier 4 is the converter signal c ', cos α becomes cos ( ω _P - ω _N ) during the period T ₁ . Also during the period T ₂ and the period 1 H, cos α alternately becomes cos ( l _P - ω _N ) and cos ( ω _P + ω _N ). On the other hand, the other input signal of the multiplier 4 is the chrominance signal component in the NTSC system, and cos β becomes cos ( ω _N + Φ). In these expressions, ω _{P represents} the angular frequency of the subcarrier in the PAL system, and ω _N represents the angular frequency of the subcarrier in the NTSC system.

Therefore, the output of the multiplier 4 becomes a signal during the period T ₁ , which is expressed by the following equation ( 2 ):

cos ( ω _P - l _N ) · cos ( ω _N + Φ) = 1/2 {cos ( ω _P + Φ) + cos ( l _P - 2 ω _N - Φ)} (2)

During the period T ₂ , the output signal of the multiplier 4 alternately becomes equal to the signal expressed by this equation ( 2 ) and a signal expressed by the following equation ( 3 ):

cos ( l _P + ω _N ) · cos ( ω _N + Φ) = 1/2 {cos ( ω _P + 2 ω _P + 2 ω _N + Φ)} (3)

This output signal of the multiplier 4 passes through the bandpass filter 6 with 4.43 MHz ( ω _P ) as a chrominance signal component d 'of 4.43 MHz, the phase of which alternates with the period 1 H with respect to the B / Y axis, as in FIG. 14H represented. This chrominance signal d 'is fed to the adder 10 and added there with the luminance signal component, which is delayed by the delay circuit 51 by T _D. A color video signal b 'according to FIG. 14I is thus generated.

Since the amplitude of the chrominance signal component of the Farbvi deosignals b 'is not lowered with the 1H period to zero and the color intensity is not reduced when the color video signal b' of the PAL video reproducing system is supplied.

Fig. 15 is a block diagram of a mat with a Signalfor converter circuit according to the invention equipped type Vi is deoplattenspielers. In the figure, the plate 71 is rotated by a spindle motor 72 . While the disk 71 is rotating, the signal recorded on the disk 71 is picked up by a pickup 73 . A so-called RF signal, ie a read signal emitted by the pickup 73 , is fed to a demodulator 74 , for example an FM demodulator, so that a color video signal is demodulated. The color video signal is fed to a CCD (charge couple device) 75 . Clock pulses output by a voltage-controlled oscillator VCO 76 are applied to the CCD 75 . In the CCD 75 the Farbsi signal receives a time delay corresponding to the frequency of the clock pulses. The color video signal from the CCD 75 is fed to a variable phase shifter 77 , a burst gate circuit 78 and a sync separator circuit 79 .

In the sync separator circuit, the horizontal sync signal is separated from the color video signal and fed to the phase comparator 80 as a playback horizontal sync signal. In the phase comparator circuit 80 , phase comparison is performed between a reference horizontal sync signal supplied from the reference signal generating circuit 81 and the reproduction horizontal sync signal, and a time base error signal corresponding to the phase difference which generates signals. The time base error signal is fed to an equalizer 82 . The gain and phase compensation for the time base error signal are performed in the equalizer 82 and a control voltage for the VCO 76 is generated, and a drive signal for the spindle motor 72 is generated. The drive signal generated by the equalizer 82 is applied to the spindle motor 72 through the drive circuit 83 , and the speed of the plate 71 is controlled so that the phase difference between the reference and the playback horizontal sync signal corresponds to a predetermined value . The control voltage generated in the equalizer 82 is supplied to the VCO 76 , for example, and the signal delay time in the CCD 75 is controlled so that the phase difference between the reference and the playback horizontal sync signal corresponds to a predetermined value. The time base error is compensated in this way.

In the burst gate circuit 78 , on the other hand, a color burst signal or a pilot burst signal is separated from the color video signal and fed to the phase comparator 85 . In the phase comparator 85 , a phase comparison is carried out between this burst signal and a reference subcarrier signal originating from the reference signal generator circuit 81 , and a phase error signal corresponding to the phase difference of the two signals is generated. The phase error signal is supplied to the variable phase shifter 77 and the color video signal is phase-shifted such that the phase of the color burst signal is equal to the phase of the reference subcarrier signal. The color video signal output from the variable phase shifter 77 is supplied to a character insertion circuit 86 . The character set circuit 86 is designed so that it generates a video signal accordingly characters, the characters designated by a system control (not shown) output data correspond to the reference signal r ₃ , which comes from the reference signal generating circuit 81 and the generated Vi uses deo signals in the color video signal.

In the reference signal generator circuit 81 , the reference horizontal sync signal is output via a movable contact C _{3 of} the switch SW ₃ . An output signal of a reducer 81 b is fed to a stationary contact A _{3 of} the switch SW ₃ . The coaster 81 b is laid out so that it reduces the frequency of the signal, which is derived from a movable contact of a switch SW ₈ , by a factor of 1/910. The stationary contacts A ₈ and B _{8 of} the switch SW ₈ are supplied with output signals from the oscillators 81 a and 81 g. The oscillator 81 a is designed to generate a signal with a frequency of 4 fsc (N), ie four times the frequency of the color subcarrier in the NTSC system. On the other hand, the oscillator 81 g is designed to generate a signal with the frequency 4 fsc (N) · f _H (N) / f _H (P). The expression f _H (N) represents the frequency of the horizontal sync signal in the NTSC system and the expression f _H (P) represents the horizontal sync frequency in the PAL system.

The switch SW ₈ is designed to selectively output the output signal from the oscillator 81 a by connecting the movable contact C ₈ to the stationary contact A ₈ when the switching control signal present has a high level, and the output signal of the oscillator 81 g output by connecting the movable contact C _{8 with} the stationary contact B ₈ when the switching signal is low. The switch control signal input terminal of the switch SW ₈ is connected to a terminal of a switch SW _{6 of} the detent type. The power supply voltage is supplied to the terminal of the switch SW ₆ through a register R. The other terminal of the SW ₆ switch is connected to ground. A low level signal is generated at the terminal of the switch SW ₆ when it is in the "ON" position and is output as a signal format converter command signal.

At the stationary contact B _{3 of} the switch SW ₃ , an output signal of a reducer 81 e is applied, which divides an output signal from an oscillator 81 d by 240. The oscillator 81 d is designed to generate a signal of 3.75 MHz, which is the frequency of a pilot burst signal which is inserted into a certain section of the PAL color video signal in a disk with a recorded PAL color video signal.

The switch SW ₃ is designed so that its movable con tact C ₃ comes into contact with the stationary contact A ₃ to transmit the output signal of the reducer 81 b when the switching control signal is high, and the movable contact C ₃ is with the stationary contact B ₃ in connection with the transmission of the output signal of the reducer 81 e , ie the signal with the horizontal scanning frequency in the PAL system when the switching control signal has a low level. An output signal of a signal format detector circuit 87 is fed to the changeover control input terminal of this changeover switch SW ₃ . The signal format detector circuit 87 is designed, for example, to detect whether the pilot signal is inserted into the color video signal recovered from the plate and to generate a signal format detection signal which indicates whether the recovered color video signal is the PAL or the NTSC. Color video signal is. Such a signal format detector circuit is described in JP patent application 63-12 240.

The reference subcarrier signal is output by a movable contact C _{4 of} the switch SW ₄ . To a stationary contact A _{4 of} the switch SW ₄ , an output signal of a reducer 81 c is performed , which generates a reference signal r ₂ by reducing an output signal of the switch SW ₈ by 4. The output signal of the oscillator 81 d is applied to a stationary contact B _{4 of} the switch SW ₄ . The switch SW ₄ is designed so that its movable contact C ₄ comes into contact with the stationary contact A ₄ in order to pass on the output signal of the reducer 81 c when the signal level at its changeover control input terminal is high, and the movable contact C ₄ comes with the stationary contact B ₄ in connection with the optional transmission of the output signal from the oscillator 81 d , ie the signal with the frequency of the pilot burst signal when the signal level at its changeover control input is low. The output signal of the signal format detector circuit 87 is supplied to the changeover control input of the changeover switch SW ₄ .

The reference signal r ₃ is output by the movable contact C _{5 of} the switch SW ₅ . The output signal of the switch SW ₈ is supplied to the stationary contact A _{5 of} the switch SW ₅ . An output signal of an oscillator 81 f is applied to the stationary contact B _{5 of} the switch SW ₅ . The oscillator 81 f generates a reference signal, the frequency of which is four times the frequency of the color subcarrier in the PAL system. The switch SW ₅ is designed so that its movable contact C ₅ comes into contact with the stationary contact A ₅ in order to send out the output signal of the switch SW ₈ when the signal level at its changeover control input is high, and the movable contact C ₅ connects to the stationary contact B _{5 in} order to send out the reference signal r ₁ at four times the frequency of the color subcarrier in the PAL system when the signal level at its switching control input is low. The output signal of the signal format discriminator circuit 87 is applied to the control input of this switch SW ₅ .

Gnal Farbvideosi the output from the Zeicheneinsetzkreis 86 a stationary contact A is supplied to a changeover switch SW _{7 7} and also a signal format converting circuit 91st The output signal of the signal format converter circuit 91 is fed to a stationary contact B _{7 of} the switch SW ₇ . In the signal format conversion circuit 91 , switching elements are connected to each other in the same manner as in the circuit shown in FIG. 4, but the oscillators 43 and 44 are omitted. In this signal format converter circuit 91 , the reference signal r ₂ output by the reducer 81 c is fed to the multiplier 42 . The reference signal r ₁ output by the oscillator 81 f is applied to this coaster 45 , the D flip-flop 47 and the inverter 48 .

The switch SW ₇ is designed so that its movable contact C ₇ comes into contact with the stationary contact A ₇ for outputting the color video signal output by the character insertion circuit 86 when the signal level at the switching control input is high, and the movable contact C ₇ connects with the stationary contact B ₇ to send out the color video signal whose signal format is changed by the signal format conversion circuit 91 when the signal level at the switching control input is low. The color video signal derived from the movable contact C _{7 of} the switch SW ₇ is fed to the output terminal.

With the structure described, when the switch SW ₆ is switched off, the signal format conversion command signal with a low level is not output, and the output signal of the oscillator 81 a , ie the signal of 4 fsc (N) is output by the switch SW ₈ and the Switch control of the changeover switches SW ₃ to SW ₅ is carried out by the output signal of the signal format detection circuit 87 . By this operation, the recovery of information from both a disc provided with an NTSC color video signal and a disc provided with a PAL color video signal is carried out well. In this case, the color video signal from the character setting circuit 86 is directly transmitted from the changeover switch SW ₇ to the output terminal so that the color video signal recovered from the disk is passed on as it is.

When the switch SW _{6 is turned} on manually, the low level signal format converting command is issued. Then, the output signal of the oscillator 81 g , that is, the signal 4 fsc (N) * f _H (N) / f _H (P) is output from the switch SW ₈ in the reference signal generating circuit 81 . This produces the reference horizontal sync signal, the frequency of which is equal to the horizontal sync frequency in the PAL system. The Burstpha senvergleich is carried out by using as a reference the signal obtained by reducing the output signal of the oscillator 81 g by four. The conversion of the chrominance signal is also carried out using the signal obtained by reducing the output of the oscillator 81 g by four. At the same time, the output signal of the signal format converter circuit 91 is derived from the changeover switch SW ₇ .

Thus, a pseudo-PAL color video signal converted by the signal format converter circuit 91 is automatically obtained when a disc with a recorded NTSC color video signal is inserted. The horizontal sync frequency of this pseudo PAL color video signal becomes equal to the horizontal sync frequency of the regular PAL color video signal. Therefore, when the pseudo PAL color video signal is supplied to the PAL demodulator circuit shown in Fig. 18, the chrominance signal component is delayed exactly 1H so that no color error is generated in the reproduced picture. Therefore, it is sufficient in the signal format converter circuit 91 to set the delay time of the delay circuit 51 , which delays the luminance signal component, equal to the delay time of the bandpass filter 6 .

As described above, in particular a video signal format converter circuit according to the invention first reference signal with four times the frequency of the color  subcarrier generated in the PAL system, and first to third Pha Slide valve signals are based on an output signal a reduction means for reducing the first reference signals generated by four, the first to third Pha slider signals identical in frequency to that of the output si gnals of the reducer and have respective phases which are shifted in order by amounts, half of the period of the first reference signal ent speak, and a video signal is called a PAL format color vi deo signal output by changing the frequency and the Phase of the chrominance signal component and the color burst si gnals of the NTSC color video signal was obtained.

Therefore, the signal format conversion circuit is invented according to the art no analog phase shifter used to Execute phase shift by analog processing, see above that the color image is always obtained with good quality without Impairment due to changes in the operating values or tem perature properties of switching elements of phase shifters.

Claims (1)

Video signal format converter circuit, characterized in that:
a first reference signal generating means ( 44 ) for generating a first reference signal ( r ₁ ) is provided with a frequency which is four times the frequency of a color subcarrier signal in the PAL system;
Reduction means ( 45 ) is provided for reducing the first reference signal ( r ₁ ) by four;
phase shifter signal generating means ( 46 , 47 , 48 , 9 , SW₁) vorgese hen is for generating first, second and third phase signals based on an output signal of the reducer means, the first to third phase shifter signals having a frequency that is identical to the frequency of the output signals of the reducer means and their phases are sequentially shifted by an amount corresponding to half the period of the first reference signal, whereby a signal component obtained by changing the frequency and phase of a chrominance signal and a color burst signal of a video signal of the NTSC system Video signal is output as a PAL video signal.