DE3115670A1 - Video recorder with helical-track recording - Google Patents

Abstract

In a video recorder with helical-track recording, a synchronisation track is recorded along one tape edge. The invention provides for recording without this synchronisation track. The speed of the head wheel (1) is regulated from the vertical synchronisation pulses (14) scanned from the helical tracks (28). The necessary distinction between the odd-numbered and the even-numbered fields is obtained either by utilising the structure of the composite synchronisation signal (Figure 2), which differs from field to field, or by utilising the azimuth angle between the direction of the gap of the video head (2, 3) and the transverse direction of the helical tracks (28), which angle differs from helical track to helical track. <IMAGE>

Description

Video recorder with helical tracking

With video recorders, the video signal is recorded in form a frequency-modulated carrier in general such that in each case the video signal of a field is recorded along a track that falls under a given Angle runs obliquely to the edge of the magnetic tape. The angle is preferably 60. This type of recording is done with a so-called head drum or two video heads around which the magnetic tape is wrapped. The beep will be while outside the rotating head drum with a fixed head on one recorded longitudinal track parallel to the tape edge.

When playing back, care must be taken to ensure that the scanning head is accurate follows the recorded helical tracks and the scanning of a helical track within the prescribed time of e.g. the duration of a field. In the Playback it is therefore necessary to determine the location of the individual helical tracks on the Tape to recognize the correct scanning movement of the video head along of these oblique tracks steer in the prescribed time.

For this purpose it is known to run parallel to the belt edge other than the one mentioned Sound track with a further fixed head, a so-called synchronous track to record. This contains e.g. at the beginning of every second helical track, i.e. at the beginning every image, an impulse, which is the beginning of every other helical track and thus every recorded image.

These pulses are transmitted to a stationary synchronizing head Scanned point where the belt executes a pure longitudinal movement. The gained thereby Pulses are then used in a so-called servo control circuit to control the Head drum speed.

The synchronous track mentioned is next to the sound track on the magnetic tape additional space required. This space requirement is also not insignificant, since the Width of such a synchronous track for a magnetic tape with a width of 1/2 " is about 1 mm. This area of the synchronous track thus resists like the area Sound track not available for recording the video signal.

The invention is based on the object of creating a video recorder which manages without the mentioned synchronous track.

This object is achieved by the invention described in claim 1 solved. Advantageous further developments of the invention are described in the subclaims.

Due to the elimination of those previously required by the invention Synchronous track, the tape requirement can thus be reduced. With the same belt area this can extend the playing time by approx. 8%. With unchanged Arrangement of the helical tracks on the tape could be the length of a helical track and thus the recording quality increases will. A particular advantage arises if, according to an earlier application P 31 10 142, the said audio track is saved parallel to the strip edge. Then the entire magnetic tape can exclusively can be used for recording the video signal on the helical tracks. For the recording and the sampling of all recorded signals are then only Video heads required. The total increase in playing time is then 16%.

The invention is based on the following knowledge. With modern video recorders, e.g. according to the VHS system, the longitudinal tape speed is only about 2 cm / s and the relative speed of the video heads to the tape approx. 5 m / s. This is it is possible, even when the tape transport has come to a standstill in its longitudinal direction the video heads of the rotating head drum are still at one speed of almost 5 m / s and to gain an RF signal even if the track position is incorrect. Even if the video signal is disturbed, vertical sync pulses can then be generated from the sampled signal separated and used as synchronizing signals for the head wheel control. the Vertical sync pulses recorded on the helical tracks within the video signal replace those previously recorded on the synchronous track parallel to the tape edge Sync signals. The vertical sync pulses scanned by the helical tracks are for use for head wheel control, preferably prepared in a pulse shaper stage.

Embodiments of the invention are explained with reference to the drawing. FIG. 1 shows an exemplary embodiment for the utilization of the field to field different structure of the vertical synchronous mix according to the first Alternative, Figure 2.3 curves to explain the operation of the circuit according to Figure 1, FIG. 4 the utilization of the different azimuth angle according to the second alternative, Figure 5.6 curves to explain the mode of operation the use of the azimuth angle according to Figure 4 and Figure 7 is a circuit example for the alternative according to FIG. 4.

In Figure 1, the rotating head drum 1 carries the two offset by 1800 Video heads 2,3, which alternate the two fields on helical tracks of the magnetic tape 4 record.

The head wheel 1 rotates in the direction 5 and is from the magnetic tape 4 wrapped around an angle of about 2500. The head wheel 1 contains two permanent magnets 6,7, which in the head 8 with the rotation head wheel pulses 9 with from field to field alternating polarity, i.e. a repetition frequency of 25 Hz. the Pulses 9 serve as a criterion for the respective position and speed of the Head drum 1.

The signals sampled by the video heads 2.3 in the form of a frequency modulated Carriers are fed to the circuit 10, which is essentially an FM demodulator and possibly a switch between the two buttons.2,3 and contains supplies the video signal at its output. This is on line 11 of the other Signal processing supplied for image reproduction. The video signal also arrives to the synchronizing signal separation stage 12, which has the synchronous mixture at its output S delivers.

Using FIGS. 2, 3, together with FIG. 1, the evaluation of the Synchronous mixture S described for the head wheel control. Figure 2a, b, c shows this Synchronous mix S at the output of stage 12 for three successive fields No. 1,2,3. The synchronous mixture S contains front compensation pulses 13, vertical synchronizing pulses 14, rear compensation pulses 15 and line sync pulses 16. In the step 17, a key pulse 18 according to FIG. 2d is generated from the vertical sync pulse 14, which controls the gate 19 permeable. Contains during the duration of the key pulse 18 the field no. 1 a line sync pulse 16, which is thus at the output of the stage 19 appears as a sync pulse 20 according to FIG. 2e. In field no. 2 this contains Synchronous mixture S during the duration of the key pulse 18 no line sync pulse 16, so that in this field at the output of stage 12 and thus also at the output the stage 19 according to Figure 2f no pulse appears. During field # 3 a pulse 20 appears again at the output of stage 19 according to FIG. 2g.

The pulses 20 at the output of the stage 19 thus have a repetition frequency of 25 Hz and thus correspond to the sync pulses that were previously separated from the Synchronous track were scanned parallel to the tape edge. The pulses 20 are in brought the pulse shaper 21 into the form necessary for the head wheel control and then fed to the phase comparison stage 22. This, on the other hand, contains about the Line 23 the head wheel pulses 9. By phase comparison of the processed pulses 20 and the head wheel pulse 9 is a control voltage at the output of the phase comparison stage 22 UR won.

This regulates the motor 25 for driving the via the amplifier 24 Head wheel 1 so that the video heads 2,3 when scanning always exactly the helical tracks follow on the magnetic tape 4. So while the head wheel pulses 9 in a known manner are derived from the rotation of the head wheel 1, which are the helical tracks marking sync pulses are no longer derived from a separate sync track, but from the recorded video signal itself by utilizing the sync pulse mixture. A circuit of the type described for recognizing the odd or even numbers Fields are described in DE-PS 15 37 473.

FIG. 3 shows the sync pulses 20 and the head wheel pulses again 9 for successive fields No. t-3.

The control voltage is derived from the phase shift between the pulses 20.9 UR obtained according to Figure 1. With the circuit of Figure 1, it is also possible to Beginning of the odd-numbered fields each a positive pulse 20 and during of the even-numbered fields the negative sync pulse shown in dashed lines 26 to win. For this purpose, the period during of the first line sync pulse 16 according to FIG. 2b with a correspondingly time-shifted one Key pulse 18 can be queried.

Then occurs during the even-numbered fields at the output one of the key stage 19 corresponding further key stage a pulse from which the Pulse 26 according to Figure 3 can be obtained.

FIG. 4 shows the video head 2 moving the tape 1 in the direction 27 along the helical track 28 scans. The gap of the head 2 is to the transverse direction of the helical track 28 inclined at an angle of 60. The other video head 3 according to Figure 4b is opposite the transverse direction of the helical track 28 inclined by 60 opposite to the head. By This so-called azimuth angle becomes a crosstalk between adjacent helical tracks 28 decreased. If namely the head 2 with the inclination by +60 on a helical track 28 arrives, on which the recording with the head 3 with an azimuth angle of 60 has taken place, practically no signal is scanned from the track, because this is the case the angle between the head gap direction and the magnetization direction is too large is. This fact is according to the second alternative for the head wheel control exploited.

In FIG. 5 it is assumed that the video heads 2, 3 are exactly the correct ones Scan longitudinal tracks 28, i.e. the angles of the head gaps in the drawing and of the scan, the assumption that this condition occurs when the scan occurs sufficiently quickly, is permissible because with new video recorders the head gear speed their correct value very quickly achieved. By evaluating the Vertical sync signals then become sync pulses 30 at the beginning of each field while on the other hand, as in FIG. 1, the head wheel 1 generates the head wheel pulses 9 supplies. The pulses 30.9 are fed back to a phase comparison stage, whose Output voltage can cause the head wheel control. With a phase shift The control voltage UR, which is used to control the head wheel speed, arises between the pulses 30.9 serves. The time allocation between the pulses 30.9 according to FIG. 5 is then constantly adhered to. It can be seen that the pulses 30 at the beginning of each field are equal, so that here the pulses 30 are not a criterion for odd and even fields are available. It would therefore be conceivable that the pulse train 30 relative to the pulse train 9 shifts by one field, so that the head / track assignment is wrong without the control circuit noticing this. However, this condition can do not occur, as will be explained below with reference to FIG.

In Figure 6 it is assumed that, as described above, the head / track assignment is wrong, e.g. the head with the azimuth angle +60 one with the azimuth angle 60 scanned the written track. When this condition exists, both video heads are delivering 2,3 practically no more signal for the reasons described above. The impulses 30 according to Figure 5 are then no longer present, as by the very small pulses 30 'is indicated. The phase comparison stage 22 in FIG. 1 then also does not provide any Control voltage more. If the speed of the head wheel is no longer regulated, the assignment will change after a very # short time due to unavoidable deviations of the heads 2,3 to the helical tracks 28 change until finally the state again occurs according to Figure 5 and sync pulses 30 occur. Then the head wheel control resets and maintains this correct association. The undesirable false state according to Figure 6 can therefore only occur for a short time.

FIG. 7 shows the head wheel rule in a simplified representation.

development for the second alternative according to Figure 4-6. The circuit is a simplified embodiment of the circuit according to FIG. 1, the stages 17, 19 in Figure 1 are no longer necessary. At the two inputs of the phase comparison stage 22 are those derived from the vertical sync signal and in the pulse shaper 21 delivered pulses 30 according to Figure 5 with correct sampling and effective control or the pulses 30 'to be regarded as zero according to FIG. 6 in the case of incorrect sampling on the one hand and on the other hand constantly the head wheel pulses 9 from the head 8. From the The phase comparison stage 22 is used to regulate the speed by means of the control voltage UR of the motor 25 as in FIG. 1, as long as the state according to FIG. 5 is present.

Claims (4)

Claims ip Yideorecorder with helical track recording with two rotating video heads, which alternate a field along a diagonal to the Record the track running along the edge of the tape and its column opposite by an azimuth angle are inclined to the transverse direction of the tracks, the position of the helical tracks from the tape indicating synchronous signal is sampled, which by phase comparison with from the Head wheel pulse derived from head wheel rotation to control the head wheel speed is used, characterized by the following features: a) As a synchronizing signal (20,30) the vertical sync signals (14) scanned by the helical tracks (28) are used. b) The distinction between odd and even Fields are done either by evaluating what differs from field to field Distance between compensation pulses (15) and the line sync pulses (16), (Fig. 1-3) or by evaluating the different inclination of the column of the video heads (2,3) to the transverse direction of the helical tracks (28), (Fig. 4-7). 2. Recorder according to claim 1, characterized in that from the synchronous mixture (S) of the sampled video signal at a point in time in which only in every other Field a line sync pulse (16) appears, an odd number and / or the synchronous signal (20) marking the even-numbered fields is obtained. 3. Recorder according to claim 1, characterized in that in the way of pulses (20) obtained from the vertical sync pulses (i4) a pulse shaper (21) lies. 4. Recorder according to claim 1, characterized in that for utilization the different azimuth angles (Fig. 4) from the vertical sync pulses (14) the synchronous signal (30) derived from the sampled video signal and the head wheel pulses (9) applied to the inputs of the phase comparison stage (22) for the head wheel control are (Fig. 4-7).