DE1277900B - Method for the magnetic recording and reproduction of high-frequency signals, in particular television picture signals, as well as audio and / or synchronous signals - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. Cl .:

H04n

German class: 21 al -32/11

Number: 1277 900

File number: P 12 77 900.9-31 (L 50272)

Filing date: March 23, 1965

Opening day: September 19, 1968

Devices for the magnetic recording and reproduction of television image signals are reworking different principles, which are essentially determined by the number of magnetic video heads used, their fixed or rotatable arrangement and the type of tape guide in the area of these magnetic heads differentiate. The devices that have gained practical importance include a version in which a magnetic head disk with four video magnetic heads about an axis parallel to the direction of travel of the tape rotates and in which the magnetic heads one after the other approximately perpendicular to the longitudinal extent record or scan tracks running on the magnetic tape. The main characteristic of a Another known device is that a magnetic head disk with only one video magnetic head is used, which rotates in a guide drum, around which the magnetic tape in a helical Winding is performed.

In both methods, the television accompaniment and special sync signals that z. B. at the Playback will affect the speed of the head disk or the magnetic tape, with a fixed Sound magnetic head or a synchronous magnetic head in the edge areas of the magnetic tape recorded.

The present invention aims to provide the magnetic heads for the audio and synchronous tracks including associated shields and mechanisms for moving pivoting barn doors as well as devices for the precise alignment of the magnetic heads to be saved. This could also make the preamps for the sound and There is no synchronized recording.

The advantages of such a design are obvious: In addition to cost savings in the Manufacture of the device, the drive drive can be made somewhat smaller, for example a significant advance in the development of a television image recorder for home use is achieved.

An apparatus for magnetic television picture recording and reproduction is known in which a pulse generator not only supplies a picture synchronizing signal, but also, by frequency multiplication, a calibration signal for controlling the speed of the rotating magnetic head assembly, and also a signal for synchronizing an oscillator which controls the speed of the tape drive motor, and a signal for tracking synchronization. The device also includes an eddy current brake disc firmly coupled to the magnetic head assembly, a method of magnetic recording
and reproduction of high-frequency signals, in particular television image signals,
as well as audio and / or synchronous signals

Applicant:

Loewe Opta

Company with limited liability,

1000 Berlin 46, Teltowkanalstrasse. 1-4

Named as inventor:

Dipl.-Ing. Wolfgang Rank, 7701 Ueberlingen

influenced by error signals derived from a phase comparison stage via a brake coil and thus controls the speed of the magnetic head assembly.

Finally, it is well known in magnetic recording of a frequency band that Contains frequencies down to zero, the low frequencies by frequency or amplitude modulation to move to a higher frequency position. This is to avoid the efficiency when reproducing low frequencies is so low that the useful amplitude is in the order of magnitude the interference amplitude comes in.

The invention is based on the fact that in the generally common devices, the television image signal before Recording on magnetic tape frequency modulates a carrier. The recorded frequency spectrum then usually ranges from about 0.5 MHz to an upper limit value which depends on the design of the device and, for example is around 3.5 to MHz. The frequency range from 0 to 0.5 MHz was previously used in the TV image recording not used.

According to the invention there is a method for recording and reproducing one with a video signal frequency-modulated signal and one or more low-frequency signals, such as. B. Sound and / or sync signals, to or from a magnetic recording medium in that the Low frequency signals with the same magnetic head arranged in a rotating head wheel and in the same magnetic track as the video signal are recorded and that each one carrier frequency modulating low-frequency signals in a frequency

809 617/373

3 4

frequency range below the lower limit frequency chronimpulse for a Kopfradsteuerungseinrichdes video frequency spectrum to be recorded, d. H. tion 8 won. The device 8 includes a recorded below about 0.5 MHz. Phase comparator with which the phase position

The modulation of one carrier frequency each by that of the head wheel 5 or one of the audio and synchronous signals permanently connected to it is necessary because in the case of 5 eddy current brake discs 9 and the relative speeds of the images now used, synchronous pulses are compared and in which see video magnetic head and magnetic tape in the a control voltage for a brake magnet 10 of the order of magnitude of 10 to 50 m / s is not directly generated. To scan the phase position of the drawing is possible. Brake disk 9 is used by an iron fastened therein. The images from a synchronous pulse in the recording and reproducing device are supplied after amplification at an already existing frequency or a playback synchronous magnetic head 14 obtained from a fixed recording frequency multiplication or division thereof by an amplifier 13, and the conducted frequency is obtained. Its premagnetization from a quenching oscillator L is best suited to the frequency of the quenching oscillator. A carrier receives. The recording of the sync pulse erfrequency is then formed by the erasing frequency follows in an edge area of the recording, while further carrier frequencies are formed by magnetic tape. A multiplying or division of the erasing frequency is also connected to the oscillator L , an erasing magnetic head 15 which is produced. 20 with that of the record carrier in its entirety

Can be deleted as a bias current for the low-width.

The carrier frequency is used for frequency recording.

sequence, which when recording with the video strengthens an audio amplifier 17, its output span signals is modulated in frequency. voltage with supply of a premagnetization

The recording of the low-frequency signals occurs at the (erasing) frequency with a recording repeat In the new method, although no longer in gift-sound magnetic head 18 in a different Randeiner continuous magnetic track, because the video area of the magnetic tape is recorded, magnetic head, e.g. with the single-head method, each time the image is displayed (Fig. 2), the rotary

Turn the head disk once the area between the video magnetic head 4 and the diagonally to the magnetic runs over adjacent belt edges; but the 30 recording tracks running along the edge of the tape. The interruptions that occur here are so short The FM voltage generated in the magnetic head is and at the existing wavelengths so flat that an amplifier and equalizer stage 19, 20, one runs do not interfere with a later sound playback. Limiter stage 21, an FM demodulator 22 and In addition, these gaps can be remedied by a known amplifier output stage 23, at the output of which the Easily compensate for measures. 35 composite video signal is available. The syn-

Further details of the invention will be given to chronization of the head wheel during playback Hand of an embodiment shown in the drawing as follows: approximately example explained. In the drawing means with the synchronous magnetic head 14 are the

F i g. 1 is a block diagram of a known remote-recording synchronous pulse recording method keyed with a video 40, amplified in a preamplifier 16 and the magnetic head in the "recording" position, head wheel control stage 8, in which the syn-

F i g. 2 shows a block diagram of the method according to chronimpulse with the reference pulses of the head-F i g. 1 in the "playback" position, wheel or the brake disc 9 can be compared.

F i g. 3 is a diagram from which the elements - The control stage 8 supplies one of the phase deviation of the total spectrum to be recorded according to 45 between the synchronous and reference pulses the invention is apparent, dependent control voltage for exciting the braking

F i g. 4 is a block diagram of the receiving side of the magnet 10, which controls the speed of the brake according to the invention Process, disc and thus the head wheel influenced.

Fig. 5 is a block diagram showing the playback. The magnetic head 18 is connected to the input of a

add page. 4 shows 50 amplifier and equalizer 24 connected to the

6a to 6c each have a magnetic tape section followed by a sound output amplifier stage 25. Magnetic tracks, which are marked by hatching. According to the invention, the stages 13, 16

nete synchronous frequency included, and and 24 and the synchronous magnetic head 14 and the

FIGS. 6d to 6f each have a sound magnetic head 18, as in FIGS. 6a to 6c, if the video listener is listening to the video Diagram to illustrate the magnetic head 4 (FIG. 4) shows a frequency spectrum occurring phase positions between the synchronous Fig. 3 is supplied. The parameters of the Diaquence and reference frequency. gramms in Fig. 3 are the winding of the

In Fig. 1, the video signal to be recorded video magnetic head 4 flowing head current Ι _κ (BAS signal) is amplified in an amplifier 1 and the frequency of the spectrum to be recorded, and fed to a modulator 2, in which the 60 The actual composite video signal takes a video signal Carrier modulated in frequency. Range from about 0.5 to 4.5 MHz, the carrier then amplified in an amplifier 3 being at 3.5 MHz. The area between the FM signal feeds a combined recording 0 and 0.5 MHz is therefore for recording playback video magnetic head 4, which is arranged in a rotating, sound and synchronous signal and given head wheel 5. 65 if further signals are free, each of which has a carrier in

From the video signal, the amplitude or frequency modu sync pulses are generated at the same time separated in a stage 6 and in lieren. The carrier for the synchronizing signal can be one Integration level 7, the vertical (image) synonymous are at 80 kHz, while the carrier

Claims (1)

5 6 for the sound is 160 kHz. The distance between lator 47 is also amplified by the pre-amplified one the carrier is chosen so that a carrier is supplied with the same playback voltage; he demodulates the the erasing frequency of the image recorder is carrier and modulated with the 10 kHz synchronous signal that the other carrier has a frequency of 80 kHz. The 10 kHz oscillation lies doubling results. When determining the position of the individual 5 on a phase bridge, they are part of the head gear Carriers and sidebands must be paid attention to control circuit 39 is. In the phase bridge, the that no disturbing interference occurs with the first or one of the first periods per field can. the reference pulse generated by the pulse generator 11, 12 In the block diagram according to FIG. 4, that the inven- (cf. also Fig. 1) is delivered, compared, proper method in the receiving position io From FIGS. 6a to 6f it can be seen that the on shows, the video signal to be recorded passes through the magnetic tape 48 recorded 10 kHz vibration an amplifier stage 26 and an FM modulator 27. Generation 49 of the synchronous signal, the amplitude of which The FM signal and others, described in more detail below, are shown by curve 50, compared level signals are generated in a magnetic head amplifier with one of the head wheel 5 or the brake 28 amplified and with the video magnetic head 4 on 15 disk9 (Fig. 1) derived reference pulse 51 recorded on a magnetic tape. The video signal (Fig. 6d to 6f) adopt different phase positions. At the entrance, a connection 29 led to an impulse can. In the fig. 6 a to 6 c is the separation stage 30, in which the sync pulses video magnetic head 52 always in the same position for separated from the composite video signal. The magnetic head 48, which is synonymous with becoming Image sync pulses are in an integration phase that is the same as the reference pulse. stage won and then control an audio frequency The video magnetic head 52 scans as shown in FIG. 6 a source 32 of e.g. B. 10 kHz, whose vibrations when the reference pulse maximum occurs (53 in begin each field with the same phase position. F i g. 6 d) just a negative moment value of the An 80 kHz cancellation oscillator 33 which generates a cancellation 10 kHz oscillation 50 '. This corresponds to a magnetic head 34 feeds, at the same time provides a carrier lag of the Vedio magnetic head 53 with respect to frequency for a modulator 35 in which the recorded synchronous oscillation.
In Fig. 6b, the video magnetic amplitude is modulated. The modulated voltage is at the head 52 when a reference pulse maximum input of the magnetic head amplifier 28 arrives. The frame 54 (FIG. 6e) just above a zero crossing of 80 kHz of the erase oscillator 33 is used after 30 cycles of the 10 kHz oscillation 50 '. In this case of doubling in a frequency doubler stage, there is synchronism. 36 as a carrier for the television sound to be recorded, in the case of the in FIG. 6 c shown position of the video or after amplification in an amplifier 37 of a magnetic head 52 above the recorded 10 kHz modulator stage 38 is supplied. The double pulse maximum 55 (Fig. 6f), which is modulated in amplitude by the oscillation 50 at the moment of the reference tone signal, just a positive cancellation frequency (= carrier frequency) is also sampled at the oscillation maximum, which is a pre-input of the amplifier 28 of the video magnetic head 52 corresponds,
excite the aforementioned three modulated carrier- From the phase differences, the rotating video magnetic head 4 is formed in known voltages. During the video recording, the brake magnet 10 for 40 speaking reinforcement at the output of the integration stage 31 excites the brake disk 9 and thus the speed existing image sync pulses of a head wheel control of the rotating video magnetic head for so long circuit 39 is supplied, which readjusts in the same way as that until synchronism prevails. Tax level 8 in FIG. 1 works. In an image recording and playback During playback (FIG. 5) the device runs through with 45, in which the headwheel influences the FM signal scanned during the image playback of the magnetic video head 4 would be synchronized with the mains frequency or with a preamplifier 40 and a video equalizer 41 that runs the clock the control voltage the special properties with regard to its throughput speed of the magnetic tape feed,
let bandwidth have. The preamplifier 40 has, if one assumes that the line sync has a lower limit frequency of about 50 kHz, so that 50 pulses of the video signal to the frame sync pulses, the three carrier frequencies and their sidebands sen have a fixed phase position - are allowed to pass unhindered with simple ones. This is not the case with the equalizer 41 for television cameras - then, on the other hand, it has a lower limit frequency of around 500 kHz and the entire sync channel can be saved and therefore only the video frequency is allowed to pass through the line sync pulses to the spectrum during playback, while all frequencies are 55 Use a comparison with the reference pulses,
under being heavily steamed. The equalized composite video signal is processed in a limiter stage 42.
then in a demodulator stage 43 FM-demodulated and in a power amplifier 44 as 1. Method for recording or replaying amplified that it is for playback in a 60 give a with a video signal frequency television receiver or a monitor is sufficient. modulated signal and one or more The pre-amplified playback voltage is low frequency signals such. B. sound and / or also to an AM demodulator 45 for 160 kHz sync signals to or from a mage, in which the magnetic recording medium modulated with the sound, thereby the carrier frequency is demodulated. The audio frequency 65 indicates that the low frequency is then also signaled in a final audio amplifier 46 with the same in a rotating head amplifier and then stands for sound reproduction to the wheel arranged magnetic head and in the same coincidence. An AM demodulation magnetic track tuned to 8OkHz is recorded as the video signal and that each of the low-frequency signals modulating a carrier frequency is in a frequency range below the lower cutoff frequency of the recorded video frequency spectrum, i. H. below about 0.5 MHz will. 2. The method according to claim 1, characterized in that the carrier frequency or the Carrier frequencies for the low frequency signals from one in the recording and reproducing device oscillator frequency that is already present or one by frequency multiplication or -division therefrom derived frequency exist. 3. The method according to claim 2, characterized in that the carrier frequency or the Carrier frequencies for the low frequency signals are derived from the cancellation oscillator frequency. 4. The method according to claim 1 or the following, characterized in that when recording a tone frequency of z. B. 10 kHz is recorded in modulated form, that this audio frequency at the beginning of each magnetic tape recording track in the same phase position starts and synchronized by the frame sync pulses of the video signal to be recorded will. 5. The method according to claim 1 or the following, characterized in that during playback to obtain a control voltage for controlling the head wheel speed the first or one of the first periods of the recorded sync signal with one of the head wheel per revolution generated reference pulse is compared. 6. The method according to claim 5, characterized in that the reference signals from a with the head wheel firmly connected eddy current brake disc are derived in such a way that a piece of iron arranged in the brake disc causes an oscillation per revolution of the disc generated by a fixed reference magnetic head. 7. The method according to claim 1 or the following, characterized in that the with the video magnetic head The frequency spectrum to be recorded is modulated in frequency with the composite video signal of around 3 MHz bandwidth Video carrier from z. B. 3.5 MHz, one with the television audio signal of about 10 kHz bandwidth amplitude-modulated sound carriers from z. B. 16OkHz and one with a 10 kHz sync frequency in the amplitude modulated synchronic carrier of z. B. 80 kHz. 8. The method according to claim 7, characterized in that with the playback the video magnetic head sampled FM voltage to a preamplifier with a lower cutoff frequency of about 50 kHz is fed and from there to a video equalizer with a lower Cutoff frequency of about 500 kHz, one on z. B. 160 kHz tuned tone modulator and one on z. B. 80 kHz tuned sync signal demodulator arrives. 9. The method according to claim 5, characterized in that the control voltage obtained is used to regulate the belt speed. 10. The method according to claim 4 or the following, characterized in that as a synchronous signal the recorded line sync pulses of the composite video signal are used. Considered publications:
German Auslegeschrifts No. 1106 799,
094797. 1 sheet of drawings 809 617/373 9.68 © Bundesdruckerei Berlin