NL8900011A - VTR adding SSB component to synchronisation PLL - has circuits which after frequency bands of chrominance signals to counter quality losses - Google Patents

Abstract

The video input signal (1) is a CVBS - Chroma Video Blanking Sync. - type used in the NTSC system. The chrominance (3) and luminance (4) components of the signal are separated (2). The chrominance signal is fed via a bandpass filter 85) to limit the signal to the 2.1 to 4.1 MHz band. Further filters (6,7) separate the double side band component (C1) from the lower frequency single side band component (C2). The single side band component is added (8) to the output of a synchronisation phase-locked-loop (20,21). After further filtering (9), the signal is added (10) to the delayed (11) double side band signal. The combined chrominance signal (f) which is in the 3.1 to 4.1 MHz band is then frequency converted (12) and added (13) to the frequency modulated (14) version of the luminance signal. The resultant signal (h) is amplified (15) and fed to the head (16). On playback similar circuits reconstitute the NTSC signal.

Description

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PHQ 89.001 1 N.V. Philips' Incandescent lamp factories in Eindhoven.

Device for recording and / or reproducing a chrominance signal.

The invention relates to a device for recording a chrominance signal in a track on a magnetic record carrier, comprising - an input terminal for receiving the chrominance signal, 5 - a writing device for recording the chrominance signal in the track, with an input coupled to the input terminal. The invention also relates to a device for reproducing a chrominance signal from a track of a magnetic record carrier. Such devices are described in Dutch patent application 87.01.348 (PHJ 87.002). In the device described therein, a luminance signal is recorded together with the chrominance signal in the magnetic record carrier. The device makes it possible to draw a larger frequency range of the luminance signal than was previously possible on a video recorder at 15. This is achieved by filtering out the high-frequency part of the luminance signal, which could not be recorded in the video recorders known so far, and converting it in frequency into the frequency range in which the low-frequency part of the luminance signal is located. In this frequency range, the two signal parts are intertwined in frequency. On display, both signal parts can be split again and the frequency-down transformed high-frequency portion of the luminance signal is again up-transformed into the frequency region in which the high-frequency portion was before recording. In this way a recording and reproducing system has been realized whereby a luminance signal lying in a larger (wider) frequency range can be recorded and reproduced. This means less quality loss in the luminance signal due to the recording and playback by a video recorder.

The device still has the drawback that only a limited frequency range of the frequency spectrum of the chrominance signal can be recorded. The result is a loss of quality 890001 f> u PHQ 89.001 2 in the chrominance signal reproduced by the device.

The object of the invention is now to provide a device with which this loss of quality can at least largely be prevented.

The recording device according to the invention is for this purpose characterized in that the input terminal is coupled to an input of a filter device which is further provided with a first and a second output, which filter device is arranged for deriving from the signal applied to its input a high-frequency signal part, and a low-frequency signal part substantially complementary thereto, and is adapted to supply the high-frequency signal part to the first, and the low-frequency signal part to the second output, the second output being coupled to an input of a modulator, that an output of the modulator and the first input of the filter device are coupled to a first and second input of a signal combining unit, respectively, that the modulator is arranged for converting the low-frequency signal part into a frequency area in which the high-frequency signal part is located, such that, after combining the The converted low-frequency signal part with the high-frequency signal part in the signal combining unit, the converted low-frequency signal part and the high-frequency signal part are interwoven in frequency, and that the signal combining unit is arranged to supply the combined signal to an input of the writing device.

By not filtering out the low-frequency part of the chrominance signal, but modulating it upwards into the frequency range in which the high-frequency part of the chrominance signal is located, which, after combining the two signal parts, are intertwined in frequency in this frequency range, this low-frequency part can nevertheless be recorded on the record carrier. The low-frequency signal part can thereby be converted to the frequency region in which the high-frequency signal part is located such that the mutual distance, seen along the frequency axis 35, between the signal components of the converted low-frequency signal part and the signal components of the high-frequency signal part is approximately fH / 4 where fH is the line frequency.

89 00011.

* * PHQ 89.001 3

In order to also be able to reproduce the chrominance signal recorded in this manner, the display device provided with a reading device for reading a signal from the track, with an output coupled to an output terminal for outputting the chrominance signal, has the feature that the output of the reading device is coupled to an input of a separating unit which is further provided with a first and a second output, which separating unit is arranged for separating the low-frequency signal part of the high-frequency signal part converted to the said frequency range from each other, and for feeding the converted low-frequency signal portion to the first output and for feeding the high-frequency signal portion to the second output, the first output is coupled to an input of a modulator, which modulator is adapted to mix back the converted low-frequency 15 signal part to the original A significant frequency range in which the low-frequency signal part was located, that an output of the modulator and the second output of the separating unit are coupled to inputs of a signal combining unit, one output of which is coupled to the output terminal. In this way, the full chrominance signal becomes available again. After converting the low-frequency signal part to the frequency range in which it is located before recording, the chrominance signal thus obtained can be combined with the luminance signal and the full video signal is available again for display on a television set.

The invention will be explained in more detail below with reference to a number of exemplary embodiments in the figure description. Fig. 1 shows an exemplary embodiment of a device for recording a video signal on a magnetic record carrier, Fig. 2 frequency curves of signals present at various points in the circuit of Fig. 1, Fig. 3 an exemplary embodiment of a display device, Fig. 4 shows the chrominance separating stage the circuit 35 of figure 3, figure 5 shows some frequency curves to further explain the circuit of figure 4, 8900011.

* - PHQ 89.001 4 Figure 6 shows the cross-talk compensation unit from the circuit of Figure 3, and Figure 7 shows some frequency curves to further explain the operation of the circuit of Figure 6.

Figure 1 shows a pickup device with an input terminal 1, for receiving a composite video signal, or a CVBS (chroma-video blanking-sync) signal, ie a signal containing both the chroma and the luminance component of the video signal contains. This is a video signal of the NTSC type. Its frequency characteristic is shown schematically in Figure 2a. The luminance component Y is in a frequency band of 0-4.2 MHz. The chroma component is in a frequency band from about 2.1 MHz to about 4.1 MHz.

In the frequency range from about 3.1 to about 4.1 MHz is the double sideband component (I and Q) of the chroma signal, which is modulated on a carrier fsc of 3.58 MHz.

In the frequency range from about 2.1 to about 3.1 MHz, the single side band component C2 (I) of the chroma signal is located.

The chroma signal C is intertwined in frequency with the part of the luminance signal Y located in the corresponding frequency range. In the Y / C screen 2, the chroma signal C and the luminance signal Y are separated from each other and applied to a first and second output 3, respectively. 4. The chroma signal is then fed to a band-pass filter 5 with cutoff frequencies of about 2.1 and 4.1 MHz. The frequency characteristic of the output signal of the band-pass filter 5 is shown in Figure 2b. This signal is applied to band filters 6 and 7 with cut-off frequencies of 3.1 MHz and 4.1 MHz and 2.1 MHz and 3.1 MHz, respectively. Consequently, the component of the chroma signal is present at the output of the band-pass filter 6, see figure 2c. The component C2 of the chroma signal is then present at the output of the band-pass filter 7, see Figure 2d. In modulator 8, the signal C2 is mixed with the mixing frequency f &. The mixing frequency fa has been chosen such that the chroma component C2, after mixing with f &, ends up in the frequency range between 3.1 and 4.1 MHz, see figure 2e, so in that frequency range in which the chroma component is already located. PHQ 89.001 5.

fa has been chosen to be equal to 3 63 3 · fH. This corresponds to fa = 991 kHz. The output signal of the modulator 8 is applied to a first input of a signal combining unit 10 via a bandpass filter 95 with cut-off frequencies of 3.1 and 4.1 MHz. The output signal of the bandpass filter 6 is supplied via a delay line (DL) 11 at another input of the signal combining unit 10. The delay line 11 delays the output of the bandpass filter 6 by such a time interval that is compensated for the signal delays occurring in the modulator 8 and the filter 9 in the other branch.

At the output of the signal combining unit 10 there is now present the combined chrominance signal combined in a frequency range of 3.1 to 4.1 MHz, see figure 2f. From the frequency characteristic of Figure 2f it is clear that, in the frequency range from 3.1 to 4.1 MHz, the frequency components of the signal C2 transformed upwards by frequency by means of the modulator 8, i.e. the broken arrows in Figure 2f, in frequencies 20 are intertwined with the frequency components of the signal Cf, indicated by the solid arrows. The mutual distance between the frequency components of C2 'and C2', respectively, is f, where the line frequency is. The frequency components of C2 'are shifted along the frequency axis with respect to the frequency components of. The signal thus obtained is converted in the frequency converter 12 into a frequency band of + 500 kHz around a carrier wave of 629 kHz, see figure 2g and applied to a first input of a signal combining unit 13.

The output 4 of the Y / C separator 2 is coupled via an FM 30 modulator 14 to a second input of the signal combining unit 13. In the modulator 14, the luminance signal is modulated. Figure 2h shows the frequency characteristic of the output signal of the signal combining unit 13. Reference frequency 14 indicates the frequency band 35 within which the modulated luminance signal is located. Z indicates the magnitude of the frequency swing of the carrier wave. This frequency sweep is about 1 MHz and is located at 89 00011 PHQ 89.001 6 between about 3.4 and about 4.4 MHz. The output signal of the combining unit 13 is then supplied via a writing amplifier 15 to a writing device 16. The writing device 16 may comprise a head drum (not shown), with one or more write heads 17 for writing the signal in a track on a magnetic record carrier 18.

The frequency fa can, for example, be derived from the line frequency. To this end, the output 4 of the Y / C separator 2 is coupled to a synchronization signal separator 20, which derives the line sync 10 from the luminance signal Y. The output of the sync separator 20 is coupled to an input of a phase-locked loop 21, which is the frequency fa derives from the line sync signal.

Figure 3 shows a display device for reproducing the signal of Figure 2h, as it is recorded with the device 15 of Figure 1. The device comprises a reading device 30 for reading a signal from a track on the record carrier 31. assuming that the reader 30 can read the signal from the track without time errors. The reading device 30 may again contain a head drum (not shown), with one or more display heads 32 thereon. The reading device 30 is coupled via an head amplifier 33 to an input 36 of a filter device 34. The filter device 34 contains a high-pass filter 35 between the input 36 and an output 37 and a low-pass filter 38 between the input 36 and the output 39. Both filters have a cut-off frequency of approximately 1.1 MHz. The luminance signal is present at the output 37, in the form shown in accordance with the curve 14 in Figure 2h. After demodulation in the FM demodulator 40, the signal Y as shown in Figure 2a is obtained. This signal is applied to first input 41 of a signal combining unit 42.

At the output 39 the chrominance signal C1 + C2 ', as indicated in figure 2h, is available. In the frequency converter 43, the chroma signal is reset to the frequency range from about 3.1 to about 4.1 MHz, see Figure 2f. The signal is applied to the input 54 of a separating stage 45 via a cross-talk compensation unit 44. This separating stage 45 separates the frequency-interlaced single-side band chroma component C2 'from the double-side band chroma component C.j. The single sideband component C2 ', in 8900011 · PHQ 89.001 7 in the form shown in Figure 2e, is supplied to the output 46. Via the bandpass filter 48 with cut-off frequencies of 3.1 and 4.1 MHz, the output signal is supplied to the demodulator 49. In in demodulator 49, the signal C2 'is mixed with the mixing frequency

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5 fa, which in turn equals 63 | fH. The mixing frequency is chosen such that the chroma component C2 ', after mixing with fa, enters the frequency range from 2.1 to 3.1 MHz, see figure 2d. After filtering in the band-pass filter 50, with cut-off frequencies of 2.1 and 3.1 MHz, the chroma signal C2 is applied to the signal combining unit 51. The chroma signal C1, see figure 2c, present at the output 47 of the separating stage 45 is passed through a delay unit 52. also applied to the signal combining unit 51. The delay unit 52 delays the signal by such a delay time that it is exactly compensated for the signal delays generated in the bandpass filters 48 and 50 and the demodulator 49.

The output signal of the signal combination unit 51 is applied to the second input 52 of the combination unit 42. At the output 53 of the signal combination unit 42, the CVBS 20 signal is again present, see figure 2a.

The separating stage 45 can be designed in the manner described in Figure 4. The separator stage includes a delay line 60 and two signal combining units 61 and 62. The delay line 60 delays the signal incoming through input 54 by two line times, ie about 2H.

The frequency characteristic of the transfer from the input 54 to the output 47 is in the form of a comb structure, with maximum frequencies corresponding to the frequency components nfH of the double-sideband chroma component (I and Q components) and 30 maximum frequencies lying midway therebetween, see figure 5b. The frequency characteristic of the transfer from the input 54 to the output 46 is in the form of a comb structure, with maximum frequencies exactly corresponding to the frequency components (n - ^ -) fH of the single side band chroma component c2 'and maximum frequencies 35 halfway lying in between, see figure 5c. Figure 5a shows again on an enlarged scale the frequency interlaced components of the two chroma signal parts and C2 '. From figure 5 8900011.

PHQ 89.001 8 * it is clear that the chroma component is produced at output 47 of the separating stage 45 and that the component C2 'appears at the output 46.

Figure 6 shows an exemplary embodiment of the crosstalk compensation unit 44. The crosstalk compensation unit 44 is intended to eliminate the crosstalk of the frequency interlaced, single side band chroma component (I), and the double side band chroma component (I and Q). in a nature trail. The crosstalk compensation unit 44 is composed of a series circuit 10 of a balanced modulator 65, a bandpass filter 66, a 1H-recursive comb filter 67, a balanced modulator 68 and a bandpass filter 69 coupled between the input 55 and the output 56.

The bandpass filters 66 and 69 both have cutoff frequencies of 3.1 and 4.1 MHz. The recursive comb filter 67 contains an IH delay line 70 and a feedback circuit via an amplifier 71, with amplification factor k, to a signal combining unit 72. Modulators 65 and 68 are both fed the same mixing frequency via input 73.

By means of modulator 65, the combined frequency-interlaced chrominance signal C1 + C2 ', see Figure 2f, wordt is shifted by a frequency of -g fH to higher frequencies. This means that a mixing frequency f ^ equal to 2fsc + ^ fH must be supplied to the modulator 65. In the recursive 1H comb filter, the crosstalk components 25 are then filtered out and, by means of the modulator 68, the combined chrominance signal is shifted back to lower frequencies by a frequency of ffH, so that the crosstalk-free chroma signal C.1 + C2 'on the output 56 is present.

The operation of the cross-talk compensation unit 44 is further explained with reference to Figure 7.

Figure 7a shows the combined and interlaced frequency chroma signal C1 + C2 'in the frequency range of

3.1 to 4.1 MHz. This signal is written in a certain track A. For this purpose it is first shifted in phase by 90 ° (delayed in phase 35). This is indicated in figure 7b. The frequency components shift over £ fH towards lower frequencies. Should the signal of Figure 7a be in a neighboring track of track A, that is track B.

83 0001 1.

r PHQ 89.001 9 are entered, the signal is first shifted in phase by 90 ° before recording. This is indicated in figure 7c.

It is clear that the frequency components have shifted over -ξ fH towards higher frequencies.

Figure 7d shows the frequency characteristic of the signal as it is read from the track A. It is clear from this figure 7d that the signal contains, in addition to the desired frequency components, which correspond to the components of figure 7b, cross-talk components from the neighboring track B, namely at the 10 positions of the frequency components of figure 7c. After reading out, the 90 ° phase rotation must first be corrected upon recording, see figure 7e.

Figure 7f shows the frequency shifted signal by the modulator 65 over jj-fH. Figure 7g shows the frequency characteristic of the recursive 1H comb filter 67. It is clear that the crosstalk components are filtered out by filtering by means of the comb filter 67, see figure 7h. By means of the modulator 68 the signal is shifted again over g-fjj to lower frequencies, see figure 7i. Figure 7i again corresponds to the characteristic of figure 7a.

During the discussion of the device of figure 3 it has been assumed that the signal read from the record carrier is (practically) not affected by time errors. This will be the case in practice. Therefore, additional measures will be necessary to make the display device work properly even in the presence of time errors. This could mean that delay lines 52 (Figure 3) and 60 (Figure 4) should be configured as variable delay lines, for example in the form of CCD delay lines.

Via a control input of these CCD delay lines, a variable clock frequency, which follows the time errors, can then be supplied in order to realize a variable delay time in these delay lines 52 and 60.

Likewise, it will be necessary to make the frequency fa supplied to the modulator 49 variable and run with the magnitude of the time errors in the read signal.

For example, the information about the time errors in the read signal can be obtained by means of an 8900011 4 PHQ 89.001 10

sync separator (not shown) which is coupled to the output of the reproduction amplifier 33. This sync separator then gives information about the line frequency fH 'varying due to the time errors that occur during reading. This line frequency fH 'can be written as 5 fH + df, where df the variations around the correct line frequency fH

to be. Starting from this, the correct clock frequencies for controlling the various elements can then be realized together with the internal oscillator in the display device supplying the frequency fsc.

It is to be noted that the invention is not limited to only the exemplary embodiments shown. The invention also applies to those exemplary embodiments which differ from the exemplary embodiments shown in points which do not relate to the invention.

89 0001 1 -

Claims (8)

Device for recording a chrominance signal in a track on a magnetic record carrier (18), comprising - an input terminal (1) for receiving the chrominance signal, - a writing device (16) for recording the chrominance signal in the track, with an input coupled to the input terminal, characterized in that the input terminal is coupled to an input of a filter device (6,7), which further comprises a first and a second output, which filter device is adapted to derive a signal applied to its input from a high-frequency signal part (C1), and a low-frequency signal part (C2) substantially complementary thereto in frequency, and is arranged for supplying the high-frequency signal part to the first, and the low-frequency signal part to the first second output, the second output 15 is coupled to an input of a modulator (8), which is an output of the modulator (8) and the first input of d the filtering devices are coupled to a first and second input of a signal combining unit (10), which modulator (8) is arranged for converting the low-frequency signal part (C2) into a frequency region in which the high-frequency signal part (C1) is located, such that, after combining the converted low-frequency signal part (C2 ') with the high-frequency signal part (Cj) in the signal combining unit (10), the converted low-frequency signal part (C2') and the high-frequency signal part (C ^) in frequency with each other interlaced, and that the signal combining unit (10) is arranged to supply the combined signal (C1 + C2 ') to an input of the writing device (16). 2. Device according to claim 1, characterized in that the low-frequency signal part (C2) is converted to the frequency range in which the high-frequency signal part (C2) is located, such that the mutual distance, seen along the frequency axis, between the signal components of the converted low-frequency signal portion 8900011. PHQ 89.001 12 (C2 ') and the signal components of the high-frequency signal portion (C1) is approximately fH / 4, where fH is the line frequency. 3. Device for reproducing a chrominance signal from a track of a magnetic record carrier (31), which chrominance signal is written in the track with a device according to claim 1 or 2, provided with a reading device (30) for reading a signal from the track, with an output coupled to an output terminal (53) for outputting the chrominance signal, characterized in that the output of the reader is coupled to an input (54) of a separating unit (45) further provided from a first and a second output (46.47), which separating unit is arranged for separating the low-frequency signal part (C2 ') converted from the high-frequency signal part (C1) into the said frequency range and for supplying the high-frequency signal part (C1). converted low-frequency signal portion (C2 ') to the first output (46) and for feeding the high-frequency signal portion (C2') to the second output (47), which is the first output (46 ) is coupled to an input of a modulator (49), which modulator is adapted to mix the converted low-frequency signal part back to the original frequency area in which the low-frequency signal part was located, which is an output of the modulator (49) and the second output (47) of the separation unit (45) are coupled to respective inputs of a signal combining unit (51), an output of which is coupled to the output terminal (53). Device according to claim 3, characterized in that the separating unit (45) contains a comb filter (Figure 4). Device according to claim 4, characterized in that the comb filter contains a delay line (60) with an adjustable delay time. Device according to claim 3, 4 or 5, characterized in that a cross-talk compensation unit (44) is arranged in front of the entrance (54) of the separation unit (45). Device according to claim 6, characterized in that the cross-talk compensation unit (44) contains a recursive 1H comb filter (67). 35 Device according to claim 7, characterized in that an input (55) of the cross-talk compensation unit (44) is coupled via an first modulator (65) to an input of the recursive 1H-89 00 01 1. PHQ 89.001 13 comb filter (67), an output of which is coupled via a second modulator (68) to an output (56) of the compensation unit (44). 8900011