JPH06101857B2 - Carrier color signal frequency conversion circuit - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention will be described in the following order.

A Industrial Field B Outline of the Invention C Conventional Technology D Problems to be Solved by the Invention E Means for Solving Problems F Action G Example G-1 Configuration (Fig. 1) G-2 Operation (FIG. 1) H Effect of the invention A Industrial field of application The present invention relates to a carrier color signal frequency for performing a process of converting the frequency of a carrier color signal of a luminance signal forming a color video signal and a carrier color signal. Regarding the conversion circuit.

B Outline of the Invention The present invention is a frequency used for frequency conversion of a carrier color signal in a carrier color signal frequency conversion circuit for converting the frequency of a carrier color signal forming a color video signal together with a luminance signal to the low frequency band side. The conversion signal is a second voltage control oscillator for generating a signal having a frequency equal to the carrier frequency of the carrier color signal and a signal having a frequency proportional to the line output frequency. And the first voltage controlled oscillator based on the comparison output obtained by phase comparison between the oscillation output and the burst signal in the carrier color signal, The control oscillator section divides its oscillation output to obtain a signal having a frequency equal to the line frequency, and
By controlling the oscillation output of the voltage-controlled oscillator based on the comparison output obtained by frequency division with the frequency division output obtained by dividing the oscillation output of the voltage control oscillation unit to obtain a signal having a frequency equal to the line frequency, The frequency stability of the conversion signal can be improved, and the time-axis fluctuation that occurs in the frequency-converted carrier color signal due to the frequency instability of the frequency conversion signal can be reduced. .

C Conventional Technology When a color video signal is recorded on a magnetic tape,
The luminance signal forming the color video signal and the carrier color signal are separated from each other, and the separated luminance signal is frequency-modulated luminance signal frequency-modulated on the high frequency side, and the carrier color signal is frequency converted to the low frequency side. A recording system is widely adopted in which, after being converted into a low-frequency carrier color signal, the both are mixed and supplied to a rotary magnetic head and recorded on a magnetic tape by the rotary magnetic head.

When such a recording method is adopted, a frequency conversion circuit for frequency-converting the carrier color signal to the low frequency band side is used. FIG. 2 shows a conventional carrier proposed to perform such frequency conversion. 2 shows a color signal frequency conversion circuit.

In the circuit shown in FIG. 2, a carrier color signal C _C having a carrier frequency component of frequency f _SC , for example, about 3.58 MHz, which is separated from the color video signal, is fed through the input terminal 11 to the carrier color signal frequency. It is supplied to the conversion unit 12. Then, the frequency conversion signal S _X is also supplied to the frequency conversion unit 12 from the conversion signal formation unit 13. Further, the conversion signal forming unit 13 outputs an oscillation output signal Sa of a crystal voltage controlled oscillator (VXO) 14 for generating a signal having a frequency f _SC ,
A frequency proportional to the line frequency f _H (about 15.75 kHz), for example, the oscillation output signal Sb of the voltage controlled oscillator (VCO) 15 that should generate a signal having 378 · f _H is divided by 1/8 in the frequency divider 16. And the resulting signal Sc, which should have a frequency f _L = 378 · f _H / 8.

The crystal voltage controlled oscillator 14 is a phase locked
The phase control is performed by forming a loop (PLL), and the phase of the burst signal St in the carrier color signal C _C supplied to the frequency conversion unit 12 extracted through the burst gate unit 17 And the phase of the oscillation output signal Sa of the crystal voltage controlled oscillator 14 are compared in the phase comparison unit 18, and the comparison output obtained from the phase comparison unit 18 is supplied to the low pass filter (LPF) 19 so that the low pass filter Based on the control signal Spc obtained at the output side of 19,
The oscillation phase of the crystal voltage controlled oscillator 14 is controlled.
As a result of such control, the oscillation output signal Sa of the crystal voltage controlled oscillator 14 has the frequency f _SC , and its phase is the burst signal St in the carrier color signal C _C supplied to the frequency conversion unit 12.
It is assumed to be synchronized with the phase of.

On the other hand, the voltage-controlled oscillator 15 is supposed to be frequency-controlled, and the frequency of the signal Sd obtained by dividing the oscillation output signal Sb of the voltage-controlled oscillator 15 by 1/378 in the frequency divider 20, The horizontal synchronizing signal S _H in the luminance signal forming the color image signal together with the carrier color signal C _C supplied through the terminal 21 is compared in the frequency comparison unit 22, and the comparison output obtained from the frequency comparison unit 22 is a low-pass signal. By being supplied to the filter 23, the oscillation frequency of the voltage controlled oscillator 15 is controlled based on the control signal Sfc obtained at the output side of the low pass filter 23. Results of such control, the signal Sc from the frequency divider 16 obtained by the 1/8 frequency-divided oscillation output signal Sb of the voltage controlled oscillator 15, the frequency f is set based on the frequency of the horizontal synchronizing signal S _H It is assumed to have _L.

Then, in the conversion signal forming unit 13, the oscillation output signal Sa of the frequency f _SC from the crystal voltage controlled oscillator 14 and the signal Sc of the frequency f _L from the frequency dividing unit 16 are supplied to the above-mentioned frequency conversion unit 12. that the frequency conversion signal Sx is, the frequency f _X
= F _SC + f _L. As a result, in the frequency conversion unit 12, the carrier color signal C _C supplied through the input terminal 11 has the carrier component of the frequency f _SC based on the frequency conversion signal S _X and has a frequency f _X −f _SC =
frequency conversion to be a f _L, from the frequency converter 12, the low-band carrier color signal C _L is obtained with a carrier component of the frequency f _L.

In this way, the low-frequency carrier color signal C _L obtained by frequency-converting the carrier color signal C _C to the low frequency band side is obtained at the output terminal 24 connected to the output end of the frequency conversion unit 12. .

D Problems to be Solved by the Invention In the conventionally proposed carrier color signal frequency conversion circuit as described above, the frequency 37 proportional to the line frequency f _H is used.
Voltage-controlled oscillator 15 for generating 8 · f _H oscillation output signal Sb
Of the frequency control, since the horizontal synchronizing signal S _H in the luminance signal to form a color video signal is used in conjunction with the carrier chrominance signal C _C, the horizontal synchronizing signal S _H in the luminance signal line frequency f _H of the normal It is required to have, for example, when the luminance signal and the carrier color signal are separated from the reproduction output of the color video signal recorded on the magnetic tape after a plurality of divings are repeated, etc. In
The horizontal synchronizing signal S _H in the luminance signal includes an error with respect to the regular line frequency f _H generated each time dubbing is performed. Therefore, the horizontal synchronizing signal S _H used for frequency control of the voltage controlled oscillator 15 has a regular line frequency f _H. There is a risk that the voltage-controlled oscillator 15 is not controlled to a proper frequency because it does not have f _H. When the horizontal synchronizing signal S _H does not have the normal line frequency f _H and the frequency control of the voltage controlled oscillator 15 is not performed properly, the frequency converting signal S _X obtained from the converting signal forming unit 13 is obtained. Since the frequency stability of the frequency conversion signal S _X is impaired, the low-frequency carrier color signal obtained by the frequency conversion in the frequency conversion unit 12 performed on the basis of the frequency conversion signal S _{X has} a frequency difference of the frequency conversion signal S _X. It includes a considerable amount of time-axis fluctuation caused by instability.

In view of such a point, in the present invention, when the carrier color signal is frequency-converted to the low frequency band side to obtain the low-frequency carrier color signal, the frequency conversion signal for the carrier color signal is equal to the carrier frequency of the carrier color signal. The oscillation output of the first voltage control oscillator, which has a frequency and whose phase is controlled to generate a signal synchronized with the phase of the burst signal in the carrier color signal, and a signal having a frequency proportional to the line frequency It is formed on the basis of the oscillation output of the second voltage-controlled oscillator that is frequency-controlled to be generated. Moreover, not only the phase control of the first voltage-controlled oscillator but also the frequency control of the second voltage-controlled oscillator is performed. It is always performed properly and the frequency conversion signal has excellent frequency stability.For example, the carrier color signal is reproduced from the output of the color video signal recorded on the magnetic tape by repeating the dubbing multiple times. Even a place in which has been released,
An object of the present invention is to provide a carrier color signal frequency conversion circuit in which a time base fluctuation generated in a low frequency carrier color signal due to frequency instability of a frequency conversion signal is reduced.

E Means for Solving the Problems To achieve the above-mentioned object, the carrier color signal frequency conversion circuit according to the present invention should generate a signal having a frequency equal to the carrier frequency of the carrier color signal supplied as an input signal. A first voltage controlled oscillator, a second voltage controlled oscillator that should generate a signal having a frequency proportional to the line frequency, an oscillation output of the first voltage controlled oscillator, and an oscillation of the second voltage controlled oscillator. The first voltage controlled oscillator includes a conversion signal forming unit that obtains a frequency conversion signal from the output, and a frequency conversion unit that frequency-converts the carrier color signal to the low frequency band side based on the frequency conversion signal. On the other hand, a first transmission control unit for controlling the first voltage control oscillation unit based on a comparison output obtained by phase comparison between the oscillation output and the burst signal in the carrier color signal is provided, and , The second electric A first frequency divider for frequency-dividing the oscillation output of the first voltage control oscillator to obtain a signal having a frequency equal to the line frequency related to the carrier color signal, and a second voltage control for the control oscillator. A second frequency division part for frequency-dividing the oscillation output of the oscillation part to obtain a signal having a frequency equal to the line frequency, a frequency division output obtained from the first frequency division part, and a frequency division output obtained from the second frequency division part. And a second oscillation control section for controlling the second voltage controlled oscillation section based on a comparison output obtained by comparing the frequency of the divided output obtained.

In the carrier color signal frequency conversion circuit according to the present invention configured as described above, the first voltage controlled oscillator is phase-controlled by the first oscillation controller and is supplied to the frequency converter. Has a frequency equal to the carrier frequency of the carrier color signal,
An oscillation output whose phase is assumed to be synchronized with the phase of the burst signal in the carrier color signal is sent out, and the second voltage control oscillation section is frequency-controlled by the second oscillation control section to generate the first voltage. The frequency division section divides the oscillation output of the first voltage controlled oscillation section to obtain a signal having a frequency equal to the line frequency, and outputs the oscillation output that matches the frequency of the frequency division output obtained. Then, in the conversion signal forming section, a frequency conversion signal is formed based on the oscillation outputs of the first and second voltage controlled oscillation sections obtained as described above, and the frequency conversion signal is supplied to the frequency conversion section. It In the frequency conversion unit, the carrier color signal supplied as an input signal is frequency-converted based on the frequency conversion signal,
A low-frequency carrier color signal obtained by frequency-converting the carrier color signal to the low frequency band side is obtained from the frequency conversion unit.

In this way, the first voltage controlled oscillator is configured to perform phase control using the burst signal in the carrier color signal as a reference signal, and the first voltage controlled oscillator is configured to perform phase control. Since the frequency-divided output of the stabilized oscillation output obtained from the first voltage controlled oscillator is used as a reference signal for frequency control,
The phase control and the frequency control for the second voltage controlled oscillator are always properly performed, and the frequency conversion signal formed based on the oscillation output of each of the first and second voltage controlled oscillators is generated. The frequency stability is excellent, and as a result, the time base fluctuation generated in the low-frequency carrier color signal due to the frequency instability of the frequency conversion signal is reduced.

G Embodiment G-1 Structure (FIG. 1) FIG. 1 shows an example of a carrier color signal frequency conversion circuit according to the present invention. In FIG. 1, a portion corresponding to each portion in FIG. 2 described above and a second portion obtained in each portion in FIG.
Signals corresponding to the signals obtained in the figure are denoted by the same reference numerals as those in FIG. 2, and duplicate description of each of them is omitted.

In this example, in addition to the same configuration as that shown in FIG. 2 described above, the oscillation output Sa of the crystal voltage controlled oscillator 14 is supplied, and the oscillation output Sa is supplied to the line frequency f _H.
The frequency divider 25 which divides to signal is obtained with is provided, further, selectively remove the horizontal sync signal S _H to be supplied through the signal Se and the terminal 21 from the frequency divider 25, a frequency A switch 26 that supplies the comparison unit 22 is provided. The switch 26 is controlled by the switch control signal Ss supplied from the control signal terminal 27, and normally, the movable contact 26c is connected to the selection contact 26a, and the frequency divider 25 supplied to the selection contact 26a. The signal Se from is placed in a state of being taken out through the movable contact 26c.

G-2 Operation (Fig. 1) Based on such a configuration, the crystal voltage controlled oscillator 14
As in the case of FIG. 2, the phase locked loop (PLL) is formed and the phase control is performed, and the oscillation output signal Sa has the frequency f _SC and the phase is the frequency f _SC. It is synchronized with the phase of the burst signal St in the carrier color signal C _C supplied to the conversion unit 12, and is supplied to the frequency conversion unit 12 and also to the frequency division unit 25. The frequency divider 25 divides the oscillation output signal Sa by 1/277, for example,
Generate a signal Se that should have a line frequency f _H. The signal Se from the frequency divider 25 is obtained by dividing the oscillation output Sa of the crystal voltage controlled oscillator 14 that operates under the phase control by the phase locked loop, so that the line frequency f _H And is always stable and is supplied to the frequency comparison unit 22 via the switch 26.

As a result, the voltage-controlled oscillator 15 receives the signal from the frequency divider 25.
Frequency control is performed with Se as the reference signal, and the oscillation output signal Sb of the voltage controlled oscillator 15 is divided by the frequency divider 20.
Frequency of signal Sd obtained by dividing by 1/378 and switch 2
The signal Se from the frequency division unit 25 supplied via 6 is compared in the frequency comparison unit 22, and the comparison output obtained from the frequency comparison unit 22 is supplied to the low pass filter 23. Control signal obtained on the output side
The oscillation frequency of the voltage controlled oscillator 15 is controlled based on Sfc. As a result of such control, the signal S from the frequency divider 16 obtained by dividing the oscillation output signal Sb of the voltage controlled oscillator 15 by 1/8
It is assumed that c has a frequency of the signal Se from the frequency divider 25, that is, a frequency f _L set based on the line frequency f _H. At this time, the signal Se from the frequency divider 25 is always a stable signal having the line frequency f _H , so that frequency control is performed with the stable signal Se for the voltage controlled oscillator 15 as the reference signal. Accordingly, the voltage controlled oscillator 15 is always controlled appropriately in frequency so that the oscillation output signal Sb is frequency stable.

Then, in the conversion signal forming unit 13, from the oscillation output signal Sa of the frequency f _SC from the crystal voltage controlled oscillator 14 and the signal Sc of the frequency f _L from the frequency dividing unit 16, the frequency f _X = f
A frequency conversion signal Sx having _SC + f _L is formed and supplied to the frequency conversion unit 12. As a result, in the frequency conversion unit 12, the carrier color signal C _C supplied through the input terminal 11 has a carrier component of the frequency f _SC based on the frequency conversion signal S _X and has a frequency f _X −f _SC = f _L. The frequency is converted as shown in FIG.
A low-pass carrier color signal C _L having _L carrier components is obtained,
It is led to the output terminal 24. In this case, both the oscillation output signal Sa of the crystal voltage control oscillator 14 and the oscillation output signal Sb of the voltage control oscillator 15 used to form the frequency conversion signal S _X are always frequency stable. Therefore, the frequency conversion signal S _X has excellent frequency stability.

In addition, when the switch 26 is brought into a state in which the movable contact 26c is connected to the selection contact 26b under the control of the switch control signal Ss, the terminal 21 supplied to the selection contact 26a.
The horizontal synchronizing signal S _{H from} is taken out through the movable contact 26c and supplied to the frequency comparison unit 22. As a result, the voltage-controlled oscillator 15 is frequency-controlled with the horizontal synchronizing signal S _H as the reference signal.
Divider 16 obtained by dividing the oscillation output signal Sb of 15 by 1/8
The signal Sc from to has a frequency f _L set based on the frequency of the horizontal synchronizing signal S _H.

H Effect of the Invention As is clear from the above description, according to the carrier color signal frequency conversion circuit of the present invention, the carrier color signal forming the color video signal together with the luminance signal is frequency-converted to the low frequency band side to lower the low frequency band. In obtaining the carrier color signal, the frequency conversion signal for the carrier color signal should be generated to have a frequency equal to the carrier frequency of the carrier color signal and whose phase is synchronized with the phase of the burst signal in the carrier color signal. The oscillation output of the first voltage-controlled oscillator that is phase-controlled and the second frequency-controlled oscillator that generates a signal having a frequency proportional to the line frequency.
Can be formed based on the oscillation output of the voltage controlled oscillator, and the phase control of the first voltage controlled oscillator is properly performed using the burst signal as a reference signal, and the frequency of the second voltage controlled oscillator is Also in the control, since the signal obtained by dividing the oscillation output of the first voltage controlled oscillator is used as the reference signal and is always properly performed, the frequency stability of the frequency conversion signal can be improved. Therefore, even if the carrier color signal is separated from the reproduced output of the color video signal recorded on the magnetic tape by repeating the dubbing a plurality of times, the color video image together with the carrier color signal is reproduced. The frequency instability of the frequency conversion signal may significantly occur when the horizontal synchronizing signal S in the luminance signal forming the signal is used as the reference signal in the frequency control of the second voltage controlled oscillator. It is possible to remarkably reduce the time-axis fluctuation caused in the low-frequency carrier color signal.

[Brief description of drawings]

FIG. 1 is a block connection diagram showing an example of a carrier color signal frequency conversion circuit according to the present invention, and FIG. 2 is a block connection diagram showing a conventional carrier color signal frequency conversion circuit. In the figure, 12 is a frequency conversion unit, 13 is a conversion signal forming unit, 14 is a crystal voltage control oscillator, 15 is a voltage control oscillator, and 16, 2
Reference numerals 0 and 25 are frequency division units, 18 is a phase comparison unit, and 22 is a frequency comparison unit.

Claims (1)

[Claims] 1. A first voltage controlled oscillator for generating a signal having a frequency equal to a carrier frequency of a carrier color signal supplied as an input signal, an oscillation output of the first voltage controlled oscillator and the carrier color. A phase comparison is performed between a burst signal in the signal and a first oscillation control unit that controls the first voltage controlled oscillator based on the comparison output, and an oscillation output of the first voltage controlled oscillator is transferred to the carrier. A first frequency divider for frequency division to obtain a signal having a frequency equal to the line frequency associated with the color signal; a second voltage controlled oscillator for generating a signal having a frequency proportional to the line frequency; A second frequency divider for dividing the oscillation output of the second voltage controlled oscillator to obtain a signal having a frequency equal to the line frequency; the frequency division output obtained from the first frequency divider; and the second frequency divider. Compare the frequency with the frequency division output obtained from the frequency division section. A frequency is generated from a second oscillation control unit that controls the second voltage control oscillator based on the comparison output, an oscillation output of the first voltage control oscillator, and an oscillation output of the second voltage control oscillator. A carrier color signal frequency conversion circuit configured to include a conversion signal forming unit that obtains a conversion signal, and a frequency conversion unit that frequency-converts the carrier color signal to a low frequency band side based on the frequency conversion signal. .