DE3739283A1 - Videotape device - Google Patents

Abstract

A videotape device with headswitching control is proposed which is suitable for replaying video signals recorded in a segmented manner. The headswitching control comprises a read-only memory in which the respective line number of particular segment transitions is stored. If the stored line number is reached by a counting process, a D-flipflop is preset and then clocked by a horizontal-frequency synchronisation signal separated from the replayed video signal.

Description

The invention relates to a video magnetic tape device the genus of the main claim.

From DE-C 2 27 06 608 is a head shift control device known for a video signal processing system with several rotatable recording and / or playback transducer heads for Consecutive scanning, one in each recorded video signal mixture from video information, Horizontal sync signals and a vertical blanking interval showing traces of a record carrier, for optional Connection of individual transducer heads each with video signal Receiving devices with a position encoder Generation of relative positions of the transducer heads with reference positional pulses representing the recording medium, a two-state circuit, the first and one second state and applied to each other following position pulses for switching between the first and the second state during the rotation of the transducers heads to a predetermined position with respect to the Record carrier conforms with a video signal receiving circuit arrangement and with the converter heads connected switches for electrical connection single heads with the video signal receiving circuit arrangement. This known head shift control device contains a synchronous signal separation circuit, which with the video signal receiving circuitry for separating the synchronization signals contained in the vertical blanking interval is coupled by the video signal, a switching pulse generator, which is coupled to the synchronizing signal separation circuit, and to the first and second states of the two-state circuit to generate multiple switching pulses,  which synchronizes with the separate sync pulses are and by a circuit for applying the switching pulses to the switches for selectively operating the switches, so with the transducer heads each with the video signal reception circuit arrangement to connect. Since only one field Head switching is possible, this can be known Device for reproducing segmented recorded Video signals are not used. As a segment the track read by a magnetic head at one revolution designated.

The object of the present invention is a video magnet tape device according to the type mentioned at the beginning which segment the signal paths assigned to the magnetic heads within horizontal blanking intervals in from Magnetic tape read video signals can be switched.

The video tape recorder according to the invention with the kenn Drawing features of the main claim has the advantage on that also reproduced from tracks of different lengths Video signals free of interference within the horizontal blanking gaps can be switched.

Different track lengths and the associated irregular segment sequences are for example in a segmented video recording format for HDTV signals (High Definition Television). Usually is used for segmented recording formats Wrapping area of the magnetic tape around the scanning device chosen larger than the area actually used. As a result, the switchover point between the two belonging to a channel, on the top wheel opposite magnetic heads within a certain Overlap area can be varied. According to the present Invention can now advantageously with the help of a Type "reference synchronization" the duration of individual segments be determined while the exact on and off points in time from those reproduced by the magnetic tape Video signals are derived.  

By the measures listed in the subclaims are advantageous further developments and improvements the arrangement specified in the main claim possible. In particular, by programming the read-only Stores any sequence of segments individually adjustable length can be specified.

Embodiments of the invention are in the drawing based on several figures in the description below explained in more detail. From the figures show:

Fig. 1 is a block diagram of a first embodiment according to the invention,

Fig. 2 voltage timing diagrams for explaining the block diagram and

Fig. 3 shows a circuit of a second embodiment according to the invention.

In Fig. 1, 1 denotes a magnetic tape that is guided around a cylindrical scanning unit by means of two tape guide elements 2 and 3 , that a rotating in a dividing joint wheel disc 4 when rotating in the direction of arrow 5, the magnetic tape in parallel, obliquely to the tape longitudinal direction describes or scans traces. The head wheel disc 4 has two diametrically opposite magnetic heads 6 and 7 on the circumference, which are used for writing or reading video signals to / from the / the magnetic tape 1 . The arrangement is such that the tape guide elements 2 and 3 determine the wrap angle of the magnetic tape 1 around the top wheel disc 4 to slightly more than 180 °, for example 190 °. As a result, there is an overlapping operation of the two magnetic heads 6 and 7 during operation, ie both magnetic heads 6 and 7 are in contact with the magnetic tape 1 in a range of approximately 10 ° rotation angle of the head wheel 4 . In the "recording" mode, there is a redundant recording of the electrical signals supplied to the magnetic heads 6 and 7 .

In the "playback" mode, only one of the two magnetic heads 6 and 7 is connected to a common playback circuit arrangement (not shown). Before switching, however, the signals generated by the magnetic heads 6 and 7 are pre-amplified in assigned amplifiers 8 and 9 . The outputs of the amplifiers 8 and 9 are connected to a controlled changeover switch 10 , to the output of which a demodulator 11 is connected. The demodulated video signal which can be taken off at the output of the demodulator 11 with terminal 12 is further processed in the following playback circuit arrangement (not shown). The synchronizing signal, which synchronizes a horizontally frequency flywheel circuit, is separated from the demodulated video signal in a device 13 . At the output of the device 13 there is thus a horizontal frequency pulse signal available which follows the horizontal synchronizing signal in the reproduced video signal. Such devices are known per se and are not the subject of this patent application.

The horizontal frequency pulse signal ( H _band ) obtained is fed to the clock input of a D flip-flop 14 . The output of the D flip-flop 14 is connected to the control input of the controlled switch 10 . The output of a read-only memory 16 is connected to the D input of the D flip-flop 14 with terminal 15 , the address inputs of which are connected to the outputs of an address counter 17 . Depending on an applied horizontal-frequency reference signal H _Ref (terminal 18 ), this address counter 17 counts up line by line until it is reset by a frame-frequency reference signal ( 2 V _Ref ) connected to terminal 19 and then starts to count up again from zero. The horizontal frequency and the frame frequency reference signal are derived in a stage 20 from a reference signal ( S _Ref ) located at a terminal 21 . The stage 20 represents a synchronous signal separator in which horizontal and vertical signal components of the reference synchronous signal are separated in a manner known per se.

The number of lines of each segment within a frame is stored in the read-only memory 16 .

The addresses for the read-only memory 16 are generated by the address counter 17 clocked horizontally or at a multiple of the horizontal frequency by counting up. The output signal of the read-only memory 16 jumps from a high to a low level or vice versa at certain segment transitions that characterize line numbers. The flip-flop 14 is set with the signal output by the read-only memory 16 and switched over by the horizontal frequency pulse signal ( H _band ) obtained from the magnetic tape. This horizontal frequency clocking ensures that switching takes place during the horizontal blanking gaps. Time errors between the synchronous signal reproduced by magnetic tape 1 and the externally supplied reference synchronous signal can be ignored by the double clocking. In addition, by appropriate selection of the segment start and segment end, the position of the segments can be placed in an area with good head-to-band contact.

The mode of operation of the block diagram shown in FIG. 1 will be explained in the following in connection with the voltage-time diagrams of FIG. 2. In FIGS. 2a and 2b, the Hüllkurvenverläufe the respectively removed from the magnetic heads 6 and 7 from the magnetic tape 1 and the preamplified signals are shown. In this case, the envelope 2b extending corresponds to Fig. 2a, the signal at the output of the amplifier 8 and the envelope curve of FIG. The signal at the output of the amplifier 9. As a result of the assumed wrap angle of the magnetic tape 1 around the scanning device and thus around the head wheel 4 with the magnetic heads 6 and 7 attached thereon, which are offset by 180 °, envelope segments which are greater than 180 ° are obtained, with sections between the envelope segments which are smaller than 180 °. According to the arrangement of the magnetic heads 6 and 7 on the head wheel 4 , the envelope segments of FIGS . 2a and 2b are shown offset by 180 ° to each other. Fig. 2c shows the horizontal rate pulse signal at the clock input of the D flip-flops fourteenth As mentioned at the beginning, this horizontal-frequency pulse signal is derived from the synchronous component of the demodulated video signal in the device 13 . At the D input of the D flip-flop 14 there is a signal according to FIG. 2d, which is used to prepare for a subsequent clocking with the horizontal frequency pulse signal read from the magnetic tape 1 ( FIG. 2c). To illustrate this process, the demodulated envelope signal at terminal 12 is shown in Fig. 2e with a larger time scale. This video signal has horizontal frequency periods ( H ) with horizontal frequency blanking intervals ( A ). The horizontal-frequency pulse signal shown in FIG. 2c is shown with a corresponding time assignment in FIG. 2f on a correspondingly larger scale. FIG. 2g likewise shows a section of the signal shown in FIG. 2d at the D input of the D flip-flop 14 on a correspondingly larger scale. It is only after a corresponding preparation by the signal at the D input of the D flip-flop 14 at time X with the positive edge of the horizontal-frequency pulse signal of FIG. 2f that the output signal of the D flip-flop becomes logic high (low) Level switched and thus switched within the blanking interval ( A ) from one video signal path to another video signal path ( Fig. 2h).

In one embodiment shown in FIG. 3, the address counter 17 and the read-only memory 16 are realized by a read-only memory 23 which is fed back via a D register 22 and which increments itself. In this case, only the next address n + 1 and all the data required as an output are in the read-only memory 23 under an address n . By feedback of the output signals of the read-only memory 23 via the D-register 22 clocked with horizontal-frequency pulses of the reference signal to the address inputs, the read-only memory 23 counts itself up. A signal at a data output of the D register sets the subsequent D flip-flop, which is then released by the next horizontal frequency pulse signal coming from magnetic tape 1 . This ensures that switching takes place only during the horizontal frequency blanking intervals. A full frame reset of the D register 22 is made possible by changing the memory address via the D register 22 .

In a video magnetic tape recorder for recording and reproducing HDTV signals for an 1125-line standard, the read-only memories 16 and 23 are programmed, for example, in such a way that the controlled changeover switch 10 is operated three times in succession after 94 line periods and then after 93 line periods is switched. After six head rotations, ie twelve segments or 1125 lines / frame, the addresses of the read-only memory 16 or 23 are counted up again.

The block diagram shown in FIG. 1 shows only one signal channel for reasons of clarity. In the case of video magnetic tape devices with a plurality of signal channels, correspondingly more magnetic heads arranged offset by 180 ° from one another are to be provided on the circumference of the head wheel disk 4 . A corresponding arrangement according to the present invention is required for each pair of magnetic heads, ie for each signal channel.

In addition, for reasons of clarity, it was assumed that the address forwarding of the read-only memory 16 or 23 is carried out line by line by applying a horizontal frequency reference signal H _Ref . Of course, it is also possible to have a signal coupled to the horizontal frequency reference signal, e.g. B. to use a signal twice the line frequency for address switching.

Claims (4)

1. Video magnetic tape device with at least two rotating magnetic heads, with a switching device for switching from the magnetic heads assigned signal paths, with a device for separating the synchronous signal from reproduced video signals and with a D flip-flop for controlling the switching device, characterized in that during playback a segmented video signal recording is fed to the clock input of the D flip-flop ( 14 ) a separated from the reproduced video signal horizontal frequency synchronous signal and that at the D input of the D flip-flop ( 14 ) there is a pulse signal, the period of which is the duration of a certain period corresponds to a reference synchronous signal derived segment length. 2. Video magnetic tape device according to claim 1, characterized in that a device ( 16 , 17 or 22 , 23 ) is provided for deriving the pulse signal, which derives segment lengths on the basis of predetermined number of lines from a reference synchronization signal. 3. Video magnetic tape recorder according to claim 2, characterized by an address counter ( 17 ), the clock input of which is fed a line-coupled reference signal and at whose reset input there is a frame-frequency reference signal, and a read-only memory ( 16 ), the address inputs of which are the address outputs of the address counter ( 17 ) are connected and at the output of which the pulse signal can be removed. 4. Video magnetic tape recorder according to claim 2, characterized by a read-only memory ( 23 ) and a D register ( 22 ), the clock input of which is supplied with a line-frequency-coupled reference signal, the D inputs of which have outputs of the read-only memory ( 23 ). are connected, a frame frequency reference signal being connected to one of the D inputs, and the outputs of which are connected to address inputs of the read-only memory ( 23 ), the pulse signal for the D input of the D flip-flop at one of these outputs Flop ( 14 ) is removable.