JPH09271040A - Magnetic reproducing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce noise such as a crosstalk component included in a chrominance signal received by a signal system discrimination device by controlling a selection output means depending whether the signal system of an input signal is the PAL-M system or the NTSC system. SOLUTION: A chrominance signal outputted from a BPF 13 is given to a noise reduction circuit 40 being a 3rd noise reduction means, a comb-line filter 20 being a 1st noise reduction means and a comb-line filter 22 being a 2nd noise reduction means. The signal passing through the noise reduction circuit 40 discriminates whether the chrominance signal outputted from a signal system discrimination device 24 adopts the PAL-M system or the NTSC system. When the signal system is discriminated to be the PAL-M system, a switch 29 is thrown to the position H and the signal given to a mixer 30 is an output signal from the comb-line filter 20. When the signal system is discriminated to be the NTSC system, the switch 29 is thrown to the position L and the signal given to the mixer 30 is an output signal from the comb-line filter 22.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a PAL-M system or an NT system for a signal reproduced from a magnetic recording medium.
The present invention relates to a magnetic reproducing device which determines whether the system is the SC system and reproduces.

[0002]

2. Description of the Related Art FIG. 5 is a block diagram for explaining an example of the configuration of a conventional magnetic reproducing apparatus. here,
As an example of a conventional magnetic reproducing apparatus, a signal system of a signal reproduced from a magnetic recording medium such as a magnetic tape is PAL-M.
A magnetic reproducing apparatus for determining whether the system is the NTSC system or not, and converting the signal system to the PAL-M system when the signal system is the NTSC system and reproducing is explained. Here, the NTSC system and the PAL-M system are types of video signal systems. In the NTSC system, the phase of a burst signal included in a color signal reproduced from a magnetic tape has a strong correlation for each horizontal scanning time. On the other hand, in the PAL-M method, the phase of the burst signal included in the color signal reproduced from the magnetic tape is inverted every horizontal scanning time, so that the correlation is strong every two horizontal scanning lines. One of the methods of determining whether the signal system to be reproduced is the PAL-M system or the NTSC system is a method of determining by detecting the presence or absence of phase inversion.

In FIG. 5, 1 is a magnetic tape which is a magnetic recording medium, 2 is a video head which is a reproducing means for reading information recorded on the magnetic tape 1 and outputting a reproduction signal,
3 is a rotary transformer and 4 is a preamplifier. The reproduction signal from the video head 2 is amplified by the preamplifier 4. The normal reproduction signal is a signal in which an FM-modulated luminance signal and a low-frequency converted color signal are mixed. Reference numeral 5 is a high-pass filter (HPF) which constitutes a separating means for separating the FM-modulated luminance signal from the reproduction signal. 6 is HPF
5 is an FM demodulator (FM DEMOD) which is an FM demodulation means for FM demodulating the luminance signal separated by 5. A low-pass filter (LPF) 7 has a function of extracting a carrier used for FM-modulating the luminance signal. Reference numeral 8 denotes a C-SYNC separator (C-SYNC SEP) for separating a sync signal included in the brightness signal from the brightness signal.
A). 9 is a burst extraction pulse (Burst Gate Pulse) for generating a pulse signal synchronized with the burst signal in order to extract the burst signal which is the reference of the phase of the color signal by inputting the synchronization signal separated by the C-SYNC separator.
se) Generator (BGP GEN).

Reference numeral 10 is a low-pass filter (LPF) which is a separating means for separating the low-pass converted color signal from the reproduced signal.
It is. Reference numeral 11 is an automatic color level adjusting circuit (A for adjusting the amplitude level of the color signal extracted by the LPF 10.
CC circuit (ACC: Abbreviation of Automatic Chromalevel Control). Reference numeral 12 is a frequency converter (CONV) which is a frequency conversion means for converting the frequency of the low-frequency converted color signal output from the ACC circuit 11 into a baseband frequency. Reference numeral 13 is a bandpass filter (BPF).

Reference numeral 14 denotes a burst sampling circuit (B) for sampling the burst signal included in the color signal when the pulse signal generated by the burst sampling pulse generator 9 is detected.
G). Reference numeral 15 is an automatic color adjustment comparator (AP) that compares the phase of a burst signal included in the color signal with the output of a crystal oscillator 16 described later and sends an output signal corresponding to the error.
C (APC: Automatic Phase Control) comparator). 16 is a crystal oscillator (XO),
Oscillates a signal having the frequency of the color subcarrier. Reference numeral 17 is a voltage controlled oscillator that controls a sub-frequency oscillator 18, which will be described later, from the error voltage from the APC comparator 15. A sub-frequency oscillator 18 oscillates a signal having the frequency of the color sub-carrier according to the control signal of the voltage-controlled oscillator 17. 1
Reference numeral 9 is a bandpass filter (BPF). Burst sampling circuit 14, APC comparator 15, crystal oscillator 16,
The voltage-controlled oscillator 17, the sub-frequency oscillator 18, and the band-pass filter 19 constitute a correction unit 50 that performs correction so as to suppress fluctuations in the frequency (baseband frequency) of the color signal converted by the frequency converter 12.

Reference numerals 20 and 22 are comb filters. Two
Reference numerals 1 and 23 denote delay lines, the delay amount of the delay line 21 is 2 horizontal scanning times, and the delay amount of the delay line 22 is 1 horizontal scanning time. The comb filters 20 and 22 are used to reduce the noise due to the crosstalk component of the color signal from the adjacent track by utilizing the correlation of the scanning lines in the horizontal direction. In the NTSC system, since the correlation is strong for each horizontal scanning line, processing is performed with the delay amount by the delay line 23 as one horizontal scanning time. In the PAL-M method, the phase of the color signal for each horizontal scanning line is inverted (here, the phase θ is set to 45 degrees as an example), and noise is reduced by utilizing the correlation in which the phases match. Therefore, the processing is performed by setting the delay amount by the delay line 21 as two horizontal scanning times. The comb filter 20 constitutes a first noise reduction means for reducing noise due to a crosstalk component included in a PAL-M type color signal, for example, a delay line 21 and resistors R1 and R2 for two horizontal scanning times. , R3.
The comb filter 22 constitutes second noise reducing means for reducing noise due to crosstalk components included in the NTSC color signal, and for example, the delay line 21 and the resistors R4, R5, R6 for one horizontal scanning time. And have.

A signal system discriminator 24 is a discriminating means for discriminating whether the signal system of the reproduced signal is the PAL-M system or the NTSC system. Signal system discriminator 24
Performs its operation when the pulse signal from the burst sampling pulse generator 9 is input. Reference numerals 25 and 26 are amplifiers. Reference numeral 28 is a signal system converter that converts an NTSC color signal into a PAL-M color signal and outputs it. Two
A switch 9 is a selection output unit that switches (that is, selectively outputs) according to the discrimination of the signal system discriminator 24.
Reference numeral 30 denotes a luminance signal output from the LPF 7 and a switch 29.
Is a mixer which is an output means for mixing and outputting the color signals selectively output by.

Next, the operation of the magnetic reproducing apparatus shown in FIG. 5 will be described. By reading the recording information recorded on the magnetic tape 1 with the video head 2, an FM-modulated luminance signal (hereinafter referred to as FM luminance signal) and a low-frequency converted color signal (hereinafter referred to as low-frequency color signal) are obtained. A reproduced signal having is reproduced. After that, the reproduction signal is amplified by the preamplifier 4 through the rotary transformer 3. The reproduced signal amplified by the preamplifier 4 is separated into an FM luminance signal and a low-pass color signal by the HPF 5 and the LPF 10, respectively.

FM separated from reproduced signal by HPF5
The luminance signal is FM demodulated by the FM demodulator 6 and then LP
The carrier wave used in FM modulation is extracted by F7.

Further, the luminance signal output from the LPF 7 is separated from the luminance signal by a C-SYNC separator 8 into a sync signal included in the luminance signal. A pulse signal is generated by the burst sampling pulse generator 9 from the sync signal separated by the C-SYNC separator 8.

On the other hand, the low-pass color signal separated from the reproduced signal by the LPF 10 is adjusted by the ACC circuit 11 so that its level becomes constant, and then the frequency converter 12, B.
It is converted into a color signal through the PF 13.

The correction means 50 controls so as to suppress the fluctuation of the frequency (baseband frequency) of the color signal converted by the frequency converter 12. As a result, the influence due to the fluctuation of the burst signal included in the color signal due to the time fluctuation accompanying the running of the magnetic tape 1 is removed, and the frequency and phase of the burst signal included in the color signal become constant.

The color signal output from the BPF 13 is input to the signal system discriminator 24, the comb filter 20 which is the first noise reducing means, and the comb filter 22 which is the second noise reducing means. The comb filters 20 and 22 reduce noise included in the color signal. As noise included in the color signal, for example, there is a crosstalk component from an adjacent track which is generated when reading the information recorded from the magnetic tape 1. The output signals from the comb filters 20 and 22 are adjusted in gain by the amplifiers 25 and 26, respectively, and output.

The signal system discriminator 24 discriminates whether the color signal output by the BPF 13 is the PAL-M system or the NTSC system. When the signal system is the PAL-M system in the signal system discriminator 24, the switch 29 is set to H.
The signal that is input to the mixer 30 by being inserted in the side is the comb filter 2
The output signal from 0 is set. Signal system discriminator 2
If the signal system in 4 is the NTSC system, the switch 29
Is placed on the L side so that the signal input to the mixer 30 becomes the output signal from the comb filter 22.

FIG. 6 shows an example of the signal system discriminator 24.
In FIG. 6, 31 is a burst gate extracting circuit, 3
2 is a phase comparator, 33 is a phase shifter, 34 is an f _h / 2 resonance circuit (f _h : horizontal scanning frequency), 35 and 36 are comparators, 37 is a reference voltage, and its magnitude is V _REF.
It is. Reference numeral 51 is a capacitor, which has a function of smoothing the output of the comparator 35. The burst gate extraction circuit 31 extracts the burst signal included in the color signal when the pulse signal output from the burst extraction pulse generator 9 is input. The burst signal extracted from the color signal is compared in phase with the reference signal (output signal of the crystal oscillator 16) of the color subcarrier phase-shifted by the phase shifter 33 by the phase comparator 32, and the phase difference is determined according to the phase difference. Output is done. The output signal of the phase comparator 32 is the f _h / 2 resonance circuit 3
After passing 4, the comparator 36 compares it with the reference voltage 37 and outputs it.

FIG. 7 shows the signal waveform of each part in the signal system discriminator 24 in the case of the PAL-M system. In FIG. 7, the horizontal axis is time. FIG. 7A shows a PAL-M system color signal. FIG. 7B shows a burst signal extracted from the color signal by the burst extraction circuit 31 at every cycle 1 / f _h (f _h : horizontal scanning frequency). FIG. 7C is a diagram showing the phase of the burst signal. Here, an example in which θ is 45 degrees will be described as an example of the phase θ of the burst signal. FIG. 7D shows PAL-
In the M mode, the output signal from the phase comparator 32 is shown.
Figure 7 (e) when the PAL-M system, shows the output signal of f _h / 2 resonant circuit 34. FIG. 7F shows the output signal of the comparator 35 smoothed by the capacitor 51.

In the case of the PAL-M system, the phase of the burst signal included in the color signal is inverted every cycle 1 / f _h .
The correlation becomes stronger in the cycle of 2 / f _h . At this time, the output signal of the phase comparator 32 has a period of 2 / f _h and a frequency of f _h / 2. Therefore, the oscillator 36 oscillates by the f _h / 2 resonance circuit 34, and the comparator 36 outputs a constant voltage equal to or higher than the voltage V _REF after being smoothed by the capacitor 51 at the next stage of the comparator 35.

FIG. 8 shows the signal waveform of each part in the signal system discriminator 24 in the case of the NTSC system. In FIG. 8, the horizontal axis is time. FIG. 8A shows N
This is a TSC color signal. FIG. 8B shows a burst signal extracted from the color signal by the burst extraction circuit 31 at every cycle 1 / f _h (f _h : horizontal scanning frequency).
FIG. 8C is a diagram showing the phase of the burst signal. NT
In the case of the SC system, the phase θ of the burst signal is 0 degree.
FIG. 8D shows an output signal from the phase comparator 32 in the NTSC system. FIG. 8E shows the case of the NTSC system,
shows the output signal of f _h / 2 resonant circuit 34. FIG. 8F shows the output signal of the comparator 35 smoothed by the capacitor 51.

In the case of the NTSC system, since the phase of the burst signal is constant regardless of the cycle 1 / f _h , the burst signal has a strong correlation every 1 / f _h . At this time, the phase comparator 32
The output signal has a period of 1 / f _h and a frequency of f _h . Therefore the f _h / 2 resonant circuit 34 because it does not oscillate by f _h / 2 resonant circuit 34, and outputs a constant voltage sufficiently smaller there than the comparator 35 at V _REF.

In this way, in the signal system discriminator 24, when the output voltage from the comparator 35 outputs a voltage higher than V _REF , the output of the comparator 36 at the next stage becomes H, and the switch 29 is switched to the H side. , Comparator 35
When the output voltage from is lower than V _REF ,
The output of the comparator 36 at the next stage becomes L, and the switch 2
By switching 9 to the L side, it is possible to output by either the PAL-M system or the NTSC system signal system.

[0021]

In the above-mentioned magnetic reproducing apparatus, the signal system discriminator 24 checks the correlation of the phases of the burst signals to determine the PAL-M system or NTSC.
The method was determined. However, in the case where the signal system discriminator 24 is configured as described above, when noise is included in the burst signal, the NTS should be discriminated from the PAL-M system due to the noise.
It may be determined to be the C method. The noise included in the color signal includes, for example, noise due to a crosstalk component generated when the video head 2 reads a signal of a track adjacent to a track to be originally reproduced, and other external noise.

How the signal system discriminator 24 malfunctions will be described with reference to FIG. FIG. 9 is a diagram for explaining how a signal in the PAL-M system is erroneously determined to be in the NTSC system by the signal system discriminator 24. FIG.
PAL the signal waveform of each part in the signal system discriminator 24.
This is a case of the -M method. In FIG. 9, the horizontal axis represents time. FIG. 9A shows a PAL-M system color signal. FIG. 9B shows a burst signal extracted from the color signal by the burst extraction circuit 31 every cycle 1 / f _h (f _h : frequency of horizontal scanning). FIG. 9C is a diagram showing the phase of the burst signal. Here, an example in which θ is 45 degrees will be described as an example of the phase θ of the burst signal. FIG. 9D shows an output signal from the phase comparator 32 in the PAL-M system. FIG. 9E shows PAL-M.
When scheme shows the output signal of f _h / 2 resonant circuit 34.
FIG. 9F shows the output signal of the comparator 35 smoothed by the capacitor 51.

In FIG. 9, it is assumed that noise such as a crosstalk component occurs during time t ₁ to t ₂ . In this case, the phase of the burst signal deviates from 45 degrees or -45 degrees, and the phase deviation causes the output value of the phase comparator 32 to decrease. When the output voltage of the phase comparator 32 is below a predetermined voltage, f _h / 2 resonant circuit 34
As a result, the resonance output is stopped and the output from the comparator 35 outputs a value equal to or lower than a constant voltage (V _REF ) during the period from t ₁ to t _2.
It is erroneously determined to be the C method.

As described above, in the conventional magnetic reproducing apparatus, when the color signal input to the signal type discriminator 24 contains noise due to a crosstalk component, there is a problem that erroneous discrimination may be made. there were. The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a magnetic reproducing apparatus having means for reducing noise such as crosstalk components included in a color signal input to the signal system discriminator 24. To aim.

[0025]

A magnetic reproducing apparatus according to the present invention is an apparatus capable of reproducing in any signal system of PAL-M system or NTSC system, and is FM-modulated from information recorded on a magnetic recording medium. Reproduction means for reproducing a reproduction signal obtained by mixing the luminance signal and the color signal subjected to the low frequency conversion,
Separation means for separating the reproduced signal into the FM-modulated luminance signal and the low-frequency-converted color signal, FM demodulation means for FM-demodulating the FM-modulated luminance signal, and low-frequency-converted color signal A frequency conversion means for converting the frequency, a correction means for correcting the frequency of the color signal converted by the frequency conversion means, and a frequency P converted by the frequency conversion means.
A first noise reduction unit that reduces and outputs noise included in the AL-M type color signal, and a second noise reduction unit that reduces and outputs noise included in the NTSC type color signal whose frequency is converted by the frequency conversion unit. It is included in the noise reducing means, the selective output means for selectively outputting one of the output signals from the first noise reducing means or the second noise reducing means, and the color signal whose frequency is converted by the frequency converting means. A third noise reducing means for reducing noise and a color signal whose noise is reduced by the third noise reducing means are used as input signals, and whether the signal system of the input signals is the PAL-M system or the NTSC system is determined. Discrimination means for discriminating and controlling the selection output means in accordance therewith, a luminance signal FM-demodulated by the FM demodulation means, and a color signal selectively output by the selection output means. Were mixed, in which an output means for outputting.

In the magnetic reproducing apparatus of the present invention, the third noise reducing means has an A / D converter for converting the corrected color signal into a digital color signal, a decoder for converting the digital color signal into a digital color difference signal, and a digital signal. A digital memory that stores a noise-reduced signal included in the color difference signal, a converter that converts the noise-reduced signal into a digital color signal, and a D / that converts the digital color signal converted by the converter into a color signal And an A converter.

The magnetic reproducing apparatus of the present invention has a third noise reducing means having a comb filter.

The magnetic reproducing apparatus of the present invention is an apparatus capable of reproducing by any of the PAL-M system and NTSC system signal systems, and the information recorded on the magnetic recording medium is F.
A reproducing means for reproducing a reproduction signal in which the M-modulated luminance signal and the low-frequency converted color signal are mixed, and the reproduction signal is F
Separation means for separating the M-modulated luminance signal and the low-frequency converted color signal, FM demodulation means for FM-demodulating the FM-modulated luminance signal, and frequency for converting the frequency of the low-frequency converted color signal. A conversion unit, a correction unit that corrects the frequency of the color signal converted by the frequency conversion unit, and a first output that reduces and outputs noise included in the PAL-M system color signal whose frequency is converted by the frequency conversion unit. NTS whose frequency has been converted by noise reduction means and frequency conversion means
A second method for reducing and outputting noise included in the C system color signal
Noise reducing means and the first noise reducing means or the second noise reducing means
Discriminating means for discriminating whether the signal system is the PAL-M system or the NTSC system and controlling the selective output means in accordance with this. And the FM demodulation means F
An output unit for mixing and outputting the M demodulated luminance signal and the color signal selectively output by the selective output unit,
The output signal from the first noise reduction means is input to the determination means.

[0029]

BEST MODE FOR CARRYING OUT THE INVENTION

Embodiment 1. FIG. 1 is a block diagram for explaining the magnetic reproducing apparatus according to the first embodiment. The magnetic reproducing apparatus according to the first embodiment includes a noise reducing circuit as a third noise reducing unit for reducing noise due to a crosstalk component included in the color signal input to the signal type discriminator 24. It is what

In FIG. 1, the same reference numerals as those in the conventional example indicate the same as or equivalent to the conventional one. In FIG. 1, 1 is a magnetic tape which is a magnetic recording medium, 2 is a video head which is a reproducing means for reading information recorded on the magnetic tape 1 and outputting a reproduction signal, 3 is a rotary transformer, and 4 is a preamplifier. The reproduction signal from the video head 2 is amplified by the preamplifier 4. The normal reproduction signal is a signal in which the FM luminance signal and the low-pass color signal are mixed. Reference numeral 5 is a high-pass filter (HPF) which is a separating means for separating the FM luminance signal from the reproduction signal. 6
Is an FM for FM demodulating the luminance signal separated by the HPF 5.
It is an FM demodulator (FM DEMOD) which is a demodulation means. A low-pass filter (LPF) 7 has a function of extracting a carrier used for FM-modulating the luminance signal. Reference numeral 8 denotes a C-SYNC separator (C-SYNC) for separating a sync signal included in the brightness signal from the brightness signal.
SEPA). Reference numeral 9 is a burst sampling pulse (Bu) for generating a pulse signal synchronized with the burst signal in order to extract the burst signal which is the reference of the phase of the color signal by inputting the synchronization signal separated by the C-SYNC separator.
rst Gate Pulse) generator (BGP GEN).

A low-pass filter (LPF) 10 is a separating means for separating the low-pass color signal from the reproduced signal. 1
Reference numeral 1 denotes an automatic color level adjusting circuit (ACC circuit (ACC: Abbreviation for Automatic Chromalevel Control)) for adjusting the amplitude level of the color signal extracted by the LPF 10. Reference numeral 12 is a frequency converter (CONV) corresponding to a frequency conversion means for converting the frequency of the low-pass color signal output from the ACC circuit 11 into a baseband frequency. Reference numeral 13 is a bandpass filter (BPF).

Reference numeral 14 denotes a burst sampling circuit (B) for sampling the burst signal included in the color signal when the pulse signal generated by the burst sampling pulse generator 9 is detected.
G). Reference numeral 15 is an automatic color adjustment comparator (AP) that compares the phase of a burst signal included in the color signal with the output of a crystal oscillator 16 described later and sends an output signal corresponding to the error.
C (APC: Automatic Phase Control) comparator). 16 is a crystal oscillator (XO),
Oscillates a signal having the frequency of the color subcarrier. Reference numeral 17 is a voltage controlled oscillator that controls a sub-frequency oscillator 18, which will be described later, from the error voltage from the APC comparator 15. A sub-frequency oscillator 18 oscillates a signal having the frequency of the color sub-carrier according to the control signal of the voltage-controlled oscillator 17. 1
Reference numeral 9 is a bandpass filter (BPF). Burst sampling circuit 14, APC comparator 15, crystal oscillator 16,
The voltage-controlled oscillator 17, the sub-frequency oscillator 18, and the band-pass filter 19 constitute a correction unit 50 that performs correction so as to suppress fluctuations in the frequency (baseband frequency) of the color signal converted by the frequency converter 12.

Reference numerals 20 and 22 are comb filters. Two
Reference numerals 1 and 23 denote delay lines, the delay amount of the delay line 21 is 2 horizontal scanning times, and the delay amount of the delay line 22 is 1 horizontal scanning time. The comb filters 20 and 22 are used to reduce the noise due to the crosstalk component of the color signal from the adjacent track by utilizing the correlation of the scanning lines in the horizontal direction. In the NTSC system, since the correlation is strong for each horizontal scanning line, processing is performed with the delay amount by the delay line 23 as one horizontal scanning time. In the PAL-M method, the phase of the color signal for each horizontal scanning line is inverted (in the first embodiment), and the delay amount by the delay line 21 is used to reduce noise by utilizing the correlation in which the phases match. Is set as 2 horizontal scanning times. The comb filter 20 is a PAL-
A first noise reducing means for reducing noise due to a crosstalk component included in the M type color signal is configured, and for example, a delay line 21 and resistors R1, R2, R for two horizontal scanning times are configured.
And 3. Comb filter 22 is NT
A second noise reducing means for reducing noise due to a crosstalk component included in the SC system color signal is configured, and includes, for example, a delay line 21 and resistors R4 and R5 for one horizontal scanning time.
R6 and.

A signal system discriminator 24 is a discriminating means for discriminating whether the signal system of the reproduced signal is the PAL-M system or the NTSC system. Signal system discriminator 24
Performs its operation when the pulse signal from the burst sampling pulse generator 9 is input. Reference numerals 25 and 26 are amplifiers. Reference numeral 28 is a signal system converter that converts an NTSC color signal into a PAL-M color signal and outputs it. Two
A switch 9 is a selection output unit that switches (that is, selectively outputs) according to the discrimination of the signal system discriminator 24.
Reference numeral 30 denotes a luminance signal output from the LPF 7 and a switch 29.
Is a mixer which is an output means for mixing and outputting the color signals selectively output by.

Reference numeral 40 is a noise reduction circuit (C-NR) which constitutes a third noise reduction means for reducing noise such as crosstalk components contained in the color signal inputted to the signal system discrimination circuit 24. FIG. 2 is a diagram for explaining an example of the noise reduction circuit 40. In FIG. 2, 41 is A /
D converter, 42 is a digital color difference signal (BY, RY) which is a digital color signal converted by the A / D converter 41.
(B: blue signal, R: red signal, Y: luminance signal)
It is a decoder (C-DEC) for converting to. 43, 44
Is a switch for switching the processing for each digital color difference signal. 45 and 47 are mixers. Reference numeral 46 is a digital memory (Field Memory) capable of storing at least information for one field of the TV signal, 48 is a converter (C-CONV) for converting a digital color difference signal into a digital color signal, and 49 is a D / A converter. Is.

Next, the operation of the noise reduction circuit 40 shown in FIG. 2 will be described. The input color signal is converted into a digital color signal by the A / D converter 41, and then converted into a digital color difference signal (BY, RY) by the decoder 42. When converted into digital color difference signals, BY and RY are independently processed by the switches 43 and 44. By mixing the digital color difference signal with the signal of one field before input to the field memory 46 by the mixer 47,
The noise component is separated from the digital color difference signal. However, in the case where the signal system is the PAL-M system, the phase of the burst signal included in the color signal changes constantly for each horizontal scanning time (here, θ is 45 degrees as an example). The digital color difference signals extracted from the decoder 4
It is necessary to configure such that signals having the same burst signal phase included in the digital color difference signal from 2 are mixed with the digital color difference signal from the decoder 42.

The noise component separated by the mixer 47 is mixed with the digital color difference signal by the mixer 45, and the digital color difference signal with the reduced noise component is recorded in the field memory 46. Further, the digital color difference signal whose noise component is reduced by the mixer 45 is converted into the converter 4
After being converted into a digital color signal by 8, the color signal is converted by the D / A converter 49 and output. Since the noise reduction circuit 40 has the above-described configuration, it is possible to reduce noise due to the crosstalk component included in the color signal.

Next, the operation of the magnetic reproducing apparatus according to the first embodiment will be described. By reading the recording information recorded on the magnetic tape 1 with the video head 2, a reproduction signal having an FM luminance signal and a low-pass color signal is reproduced. After that, the reproduction signal is amplified by the preamplifier 4 through the rotary transformer 3. The reproduction signal amplified by the preamplifier 4 is HP
The F5 and LPF10 separate the FM luminance signal and the low-pass color signal, respectively.

FM separated from reproduced signal by HPF5
The luminance signal is FM demodulated by the FM demodulator 6 and then LP
The carrier wave used in FM modulation is extracted by F7 and converted into a luminance signal.

Further, the luminance signal output from the LPF 7 is separated from the luminance signal by a C-SYNC separator 8 into a sync signal included in the luminance signal. A burst sampling pulse generator 9 generates a pulse signal synchronized with the burst signal from the synchronization signal separated by the C-SYNC separator 8.

On the other hand, the low-pass color signal separated from the reproduced signal by the LPF 10 is adjusted by the ACC circuit 11 so that its level becomes constant, and then the frequency converter 12, B.
It is converted into a color signal through the PF 13.

The correction means 50 controls so as to suppress the fluctuation of the frequency (baseband frequency) of the color signal converted by the frequency converter 12. As a result, the influence due to the fluctuation of the burst signal included in the color signal due to the time fluctuation accompanying the running of the magnetic tape 1 is removed, and the frequency and phase of the burst signal included in the color signal become constant.

The color signal output by the BPF 13 is the third color signal.
Noise reduction circuit 40 which is the noise reduction means, the comb filter 20 which is the first noise reduction means, and the comb filter 22 which is the second noise reduction means. The comb filters 20 and 22 reduce noise included in the color signal. As noise included in the color signal, for example, there is a crosstalk component from an adjacent track which is generated when reading the information recorded from the magnetic tape 1. The output signals from the comb filters 20 and 22 are amplifiers 25 and 26, respectively.
The gain is adjusted by and output.

The signal passed through the noise reduction circuit 40 determines whether the color signal output by the signal system discriminator 24 is the PAL-M system or the NTSC system.
When the signal system discriminator 24 determines that the signal system is the PAL-M system, the switch 29 is placed on the H side so that the signal input to the mixer 30 is the output signal from the comb filter 20. When the signal system discriminator 24 discriminates the signal system as the NTSC system, the switch 29 is put in the L side and the mixer 3
The signal input to 0 becomes the output signal from the comb filter 22.

In the magnetic reproducing apparatus of the first embodiment, the color signal input to the signal type discriminator 24 is passed through the noise reduction circuit 40, and the output signal of the noise reduction circuit 40 is used as the input signal of the signal type discriminator 24. Therefore, the signal system discriminator 24
Since the noise contained in the color signal input to is reduced, erroneous discrimination by the signal system discriminator 24 becomes smaller than in the conventional case.

Embodiment 2 FIG. 3 is a block diagram for explaining the magnetic reproducing apparatus according to the second embodiment. The magnetic reproducing apparatus according to the second embodiment is characterized in that the third noise reducing means is composed of a comb filter and its output is amplified by an amplifier.

In FIG. 3, the same reference numerals as those in FIG. 1 represent the same as or equivalent to those in FIG. In FIG. 3, reference numeral 38 denotes a comb filter which is a third noise reducing means for reducing noise such as crosstalk components included in the color signal. The comb filter 38 includes, for example, a delay line 39 that delays by two horizontal scanning times, a resistor R7,
It has R8 and R9. Reference numeral 27 is an amplifier for adjusting the gain.

Noise contained in the color signal, particularly noise due to the crosstalk component contained in the color signal when the signal system is the PAL-M system, is reduced by the comb filter 38, and then the gain is adjusted by the amplifier 27. It is input to the signal system discriminator 24.

In the magnetic reproducing apparatus of the second embodiment, the color signal input to the signal system discriminator 24 is passed through the comb filter 38, and the output signal from the comb filter 38 is input to the signal system discriminator 24. Therefore, since the noise included in the color signal input to the signal system discriminator 24 is reduced, erroneous discrimination by the signal system discriminator 24 becomes smaller than in the conventional case.

Embodiment 3 FIG. 4 is a block diagram for explaining the magnetic reproducing apparatus of the third embodiment. In FIG. 4, the same reference numerals as those in FIG. 1 represent the same as or equivalent to those in FIG. In the magnetic reproducing apparatus according to the third embodiment, the signal system discriminator 2 outputs the output of the comb filter 20.
It is characterized in that the configuration is such that the data is input to 4.

In the magnetic reproducing apparatus of the third embodiment, the comb filter 20 is used when the color signal is input to the signal system discriminator 24.
Since an output signal of the color filter is used as an input, noise due to a crosstalk component included in the color signal is generated by the comb filter 20.
Since the noise can be reduced in the color signal input to the signal system discriminator 24, the signal system discriminator 2 can be reduced.
No. 4 makes erroneous discrimination more than ever. Further, in order to reduce noise due to the crosstalk component of the color signal as compared with the first and second embodiments, it is included in the color signal input to the signal system discriminator 24 without providing a circuit for specially reducing the noise. It is possible to reduce noise.

Further, although the magnetic reproducing apparatus has been described in the first to third embodiments, in the magnetic recording / reproducing apparatus having the recording function, the above-mentioned first embodiment is applied to the reproducing portion.
The same effect can be obtained by applying 3 to 3.

[0053]

Since the magnetic reproducing apparatus of the present invention comprises the third noise reducing means for reducing the noise contained in the color signal, the noise contained in the color signal inputted to the discriminating means is reduced. Erroneous discrimination by the discriminating means is less than in the past.

In the magnetic reproducing apparatus of the present invention, the third noise reducing means has an A / D converter for converting the corrected color signal into a digital color signal, a decoder for converting the digital color signal into a digital color difference signal, and a digital color difference signal. A digital memory that stores a noise-reduced signal included in the color difference signal, a converter that converts the noise-reduced signal into a digital color signal, and a D / that converts the digital color signal converted by the converter into a color signal Since the A converter is provided, noise included in the color signal input to the discriminating means is reduced, and erroneous discrimination by the discriminating means is less than in the conventional case.

In the magnetic reproducing apparatus of the present invention, since the third noise removing means is provided with the comb filter, the noise contained in the color signal input to the discriminating means is reduced. Less than.

Since the magnetic reproducing apparatus of the present invention is constructed so that the output signal from the first noise reducing means is inputted to the discriminating means, the noise contained in the color signal inputted to the discriminating means is reduced. The number of erroneous discriminations by the discrimination means is smaller than in the conventional case, and the structure of the device is simplified.

[Brief description of drawings]

FIG. 1 is a block diagram for explaining a configuration of a magnetic reproducing device according to a first embodiment.

FIG. 2 is a block diagram for explaining the configuration of a noise reduction circuit in the magnetic reproducing device according to the first embodiment.

FIG. 3 is a block diagram for explaining a configuration of a magnetic reproducing device according to a second embodiment.

FIG. 4 is a block diagram for explaining a configuration of a magnetic reproducing device according to a third embodiment.

FIG. 5 is a block diagram for explaining the configuration of a conventional magnetic reproducing device.

FIG. 6 is a diagram for explaining a configuration of a signal system discriminator in a conventional magnetic reproducing device.

FIG. 7: In the conventional magnetic reproducing apparatus, the signal system is P
It is a figure for demonstrating the output inside a signal system discrimination | determination means at the time of AL-M system.

FIG. 8 shows a conventional magnetic reproducing apparatus in which the signal system is N
It is a figure for demonstrating the output inside a signal system discrimination | determination means when it is a TSC system.

FIG. 9 shows a conventional magnetic reproducing apparatus in which the signal system is P
It is a figure for demonstrating the case where the signal system discrimination | determination means makes an erroneous discrimination | determination when it is AL-M system.

[Explanation of symbols]

1 magnetic tape 2 video head 3 rotary transformer 4 preamplifier 5 high-pass filter 6 FM demodulator 7 low-pass filter 8 C-S
YNC separator 9 Burst sampling pulse generator 10 Low pass filter 11 Automatic color level adjusting circuit 12 Frequency converter 13 Band pass filter 14 Burst sampling circuit 15 Automatic color adjusting comparator 16 Crystal oscillator 17 Voltage controlled oscillator 18 Sub frequency oscillator 19 Band pass Filter 20 Comb filter 21 Delay line 22 Comb filter 23 Delay line 24 Signal system discriminator 25, 26, 27 Amplifier 28 Signal system converter 29 Switch 30 Mixer 31 Burst sampling circuit 32 Phase comparator 33 Phase shifter 34 f _h
/ 2 resonance circuit 35, 36 comparator 37 reference voltage 38 comb filter 39 delay line 40 noise reduction circuit 41 A /
D converter 42 Decoder 43, 44
Switch 45, 47 Mixer 46 Digital memory 48 Converter 49 D /
A converter 50 correction means 51 capacitor

Claims (4)

[Claims] 1. An apparatus capable of reproducing in either a PAL-M system or an NTSC system, wherein an FM-modulated luminance signal and a low-pass converted color signal are reproduced from information recorded on a magnetic recording medium. Reproduction means for reproducing the mixed reproduction signal, separation means for separating the reproduction signal into the FM-modulated luminance signal and the low-frequency-converted color signal, and FM demodulation of the FM-modulated luminance signal. FM demodulation means, frequency conversion means for converting the frequency of the low-frequency converted color signal, correction means for correcting the frequency of the color signal converted by the frequency conversion means, and frequency conversion by the frequency conversion means. Is PAL-M
First noise reducing means for reducing and outputting noise included in the color signal of the system, and NTSC whose frequency is converted by the frequency converting means.
Second noise reducing means for reducing and outputting the noise contained in the color signal of the system, and a selective output for selectively outputting one of the output signals from the first noise reducing means or the second noise reducing means. Means, a third noise reducing means for reducing noise included in the color signal whose frequency is converted by the frequency converting means, and a color signal whose noise is reduced by the third noise reducing means as an input signal, The signal system of this input signal is P
Discriminating means for discriminating between the AL-M system and the NTSC system and controlling the selective output means accordingly, a luminance signal FM demodulated by the FM demodulating means, and selective output by the selective output means. A magnetic reproducing apparatus, comprising: an output unit that mixes and outputs the generated color signal. 2. The third noise reducing means includes an A / D converter for converting the corrected color signal into a digital color signal, a decoder for converting the digital color signal into a digital color difference signal, and the digital color difference signal. A digital memory for storing a signal with reduced noise, a converter for converting the signal with reduced noise into a digital color signal, and a D / A conversion for converting the digital color signal converted by the converter into a color signal The magnetic reproducing apparatus according to claim 1, further comprising: 3. The magnetic reproducing apparatus according to claim 1, wherein the third noise reducing means has a comb filter. 4. A device capable of reproducing in either a PAL-M system or an NTSC system, wherein an FM-modulated luminance signal and a low-frequency converted color signal are reproduced from information recorded on a magnetic recording medium. Reproduction means for reproducing the mixed reproduction signal, separation means for separating the reproduction signal into the FM-modulated luminance signal and the low-frequency-converted color signal, and FM demodulation of the FM-modulated luminance signal. FM demodulation means, frequency conversion means for converting the frequency of the low-frequency converted color signal, correction means for correcting the frequency of the color signal converted by the frequency conversion means, and frequency conversion by the frequency conversion means. PAL-
First to reduce and output noise included in M type color signal
Noise reducing means and NTSC whose frequency is converted by the frequency converting means.
Second noise reducing means for reducing and outputting the noise contained in the color signal of the system, and a selective output for selectively outputting one of the output signals from the first noise reducing means or the second noise reducing means. Means for determining whether the signal system is the PAL-M system or the NTSC system, and controlling the selective output means accordingly, and a luminance signal FM-demodulated by the FM demodulating means. An output means for mixing and outputting the color signal selected and output by the selection output means, wherein the output signal from the first noise reduction means is input to the determination means. Magnetic reproducing device.