DE1191850B - Method and device for scanning magnetically stored images - Google Patents

Description

Method and device for scanning magnetically stored images The invention relates to a method and devices for scanning magnetically stored information. In particular, the invention relates to methods and means for scanning the transverse tracks stored on magnetic tape Image information and / or the sound information stored in a longitudinal track of a TV program if it is not running synchronously or if the magnetic tape has come to a standstill.

Although the magnetically stored image and sound information are in contrast can be played back immediately to a photographic recording, there is often a desire to changes, cuts, shortenings or changes after the recording has been completed Make implementations. The interfaces should be used for cutting be easy to define and locate, including fast forward and backward winding of the magnetic tape, visualization of the picture and listening to the sound required is. However, this processing of television magnetic tapes is made more difficult by that the image signal can only be recovered when the magnetic tape is running synchronously can and that defining the interface by observing the image therefore can only be done "dynamically". The one on the same magnetic tape in a longitudinal track recorded sound is also longitudinally opposite to the associated image recording of the magnetic tape offset by a certain amount. This "tonal shift" makes it difficult in addition, the simple editing of a TV magnetic tape.

So far, one has to define the interfaces on a television magnetic tape operated by an additional device that has become known as the »video finder« is. (Kino-Technik, Heft 10, 1959, S.49.) This additional device contains a rotating disk-shaped magnetic memory that is used by the drive device of the magnetic tape is driven by means of a friction clutch. While looking at the front Magnetic tape of the recovered television picture in a picture monitor is at the points at which the magnetic tape is to be cut, a marking signal is displayed on the magnetic memory recorded. This has the effect that when the tape is played back again, the television picture goes out in the monitor for a few seconds, so that in this way a control can be done through the correct attachment of the cutting signals. After this if necessary corrected, the marker signals are on the auxiliary track of the television magnetic tape transferred and thus the interfaces are set on the magnetic tape. The editing of the cut of television magnetic tapes according to this known method is therefore very complicated, the difficulties caused by the sound offset with regard to synchronous sound recording can be increased even further.

There are video cutting methods known, after which a precise tape cut over the image line is possible with the help of the cutting impulses. (Rundfunktechnische Mitteilungen, 5/1961, p. 240). To simplify editing of television magnetic tapes are in the inventive method for scanning the image information stored in parallel transverse tracks on a television magnetic tape and / or the associated sound information recorded in a longitudinal track of the magnetic tape by means of magnetic heads arranged on a rotating support for recovery of the image signal the magnetic heads transversely to the track direction against each other by the track width offset one after the other in the direction of the track with the same peripheral speed as the Recording heads repeatedly over the one containing a television picture or field Piece of magnetic tape is moved and the signals supplied by the magnetic heads are in cyclical order and forwarded to a periodically repeating one Television signal, and / or for the recovery of the audio signal is a Magnetic head moved on the sound track in such a way that the sum of the peripheral speed of the tape head and tape speed constant and equal to the tape speed when recording is.

Compared to the known cutting processes and devices, this has new cutting processes and the facilities for their implementation have the advantage, that Searched for the interface while the tape was running, and the magnetic tape when found stopped and to look at a single image even with the magnetic tape stopped and the the sound belonging to the image area can be heard.

This includes the option of stationary magnetic tape locate and control the editing site with the same facility to delimit exactly, to carry out the cut and the reconnection of the tape ends and finally the ones that are omitted during editing due to the offsetting of image and sound Sound component in the correct location, in the correct phase and in the exact length in the one on the trimmed Tape to cover the existing gap.

The new process is also suitable for cutting the ribbons and the facility for its implementation also especially for the production of special ones Tricks like those often desired in cinema image and sound technology.

In order to now create a film-appropriate tape cut for the compilation of Enable programs for change, implementations, cuts, etc. like this is common in cinema technology, the should also be closed when the magnetic tape is at a standstill the sound belonging to the still picture can be heard.

The invention is now intended to illustrate on the basis of exemplary embodiments Arrangements for carrying out the method according to the invention with the aid of the figures explained. Of the figures, FIG. 1 a section of a magnetic tape, on which transverse tracks are indicated which contain the information for a television picture, F i g. 2 a rotating magnetic head carrier in a view in the direction of the axis of rotation, F i g. 3 shows a side view and a partial section of the rotating magnetic head carrier; F i g. 4 schematically shows the arrangement of the magnetic heads on the magnetic head carrier, above a catchy screw turn distributed, F i g. 5 the one embodiment of Magnetic heads and their attachment to the rotating magnetic head carrier, F i g. 6, 7 and 8 is a schematic representation of the scanning process, FIG. 9, 10, 11 and 12 one rotating magnetic head carrier, in which a larger number of magnetic heads over a multi-start screw turn are distributed, F i g. 13 schematically shows the scanning sequence through the heads of a rotating magnetic head carrier, which has a four-start screw turn are distributed, F i g. 14 shows an illustration of the rotating magnetic head carrier with Drive for periodic axial displacement in a perspective view, F i G. 15 a detail of the device for the axial displacement of the magnetic head carrier, F i g. Fig. 16 schematically shows a television magnetic tape with image and sound recording with facilities for image and sound scanning and sound and control signal recording on one Intermediate memory, FIG. 17 a device for sampling and intermediate storage the sound information in the case of non-synchronous tape running in a perspective view, F i g. 18 details including the cutting device of a device for Sampling of the sound information when the tape is at a standstill and when the tape is running synchronously, F i g. 19 a sound pickup and cutting device with differential gear.

Parts with the same function are partly with the same in the figures Reference numerals denoted.

F i g. 1 shows a section of a television magnetic tape in which the image signal was recorded in parallel transverse tracks. In a known recording method, a complete image is stored over the distance 25 and forty transverse tracks. With the usual interlace method, the information content for a field is therefore in twenty tracks I ... XX distributed over the path 24.

To recognize the image information as a single image on the screen of a television receiver, it is sufficient to scan one field, that is to say twenty transverse tracks, with the magnetic tape 23 stationary. A device suitable for this is shown in FIGS. 2, 3 and 4 shown. This consists of a rotating head wheel 21, on the circumference of which twenty magnetic heads 1 to 20 are arranged at equal angular intervals. The magnetic heads are inserted into bores in the magnetic head carrier, which are closed by a ring 43. The scanning gaps of the heads are offset from one another in the axial direction by one track width, so that the gaps of the magnetic heads 1 to 20 appear distributed over the circumference of the head wheel 21 in the form of a single-thread screw turn, as shown in FIG. 4 is shown schematically. The spacing of the magnetic heads 1 to 20 in the circumferential direction corresponds to the length of the transverse tracks or the circumferential spacing of the heads on the head wheel used for recording. With an established recording method, this is approximately 41.3 mm. In this case the head wheel, measured along the circumference of the head gap, has a circumference of 826 mm and a diameter of 263 mm. Since a field is to be scanned in 1/10 of a second, the head wheel 21 rotates at 3000 rpm. With a single rotation of the head carrier 21, the tracks I ... XX with the information content of a field are scanned one after the other with the magnetic tape 23 at a standstill. If it is ensured that the beginning of the first line on the screen of the television receiver coincides, the scanned field will be visible on the screen in the correct position.

F i g. 3 shows the head carrier 21 in a side view and a partial section in the direction AB in FIG. 1. The attachment of the head wheel 21 on its drive axle is expediently carried out by means of a clamping cone 22. A collector 62 whose segments 1 'to 20' are connected to the associated heads 1 to 20 can serve to take off the head currents. The top currents from the collector can be drawn off via a stationary mercury contact 63, which transfers the top currents to the output line 64 .

F i g. 5 shows, greatly enlarged, the fastening of the magnetic heads 1 to 20 on the rotating head carrier 21, which makes it possible to carry out both the circumferential spacing and the lateral displacement of the head gaps with the required accuracy. For this purpose, at the points on the circumference of the head carrier 21 where the magnetic heads 1 to 20 are to be attached, in the head carrier 21 at the same angular intervals (for twenty heads 18 °), not completely through holes are provided, into which the magnetic heads, consisting of the magnetic yoke 26, the bobbin with winding 27 and the holding jaws 28 and 29 can be used.

For adjustment in the radial direction, each magnetic head is between the cylindrical holding jaws 33, 34 clamped, which are secured by the screws 35, 36 be pressed against the magnetic head. If the screws are loosened, the magnetic head is Can be moved up and down between the holding jaws. The holding jaws 33, 34 are rounded so that they fit exactly into the bores of the carrier 21, and are by means of the screw 37, which engages the holding jaw 34, and the nut 38 attached to the carrier 21.

The magnetic heads must each be offset from one another in the axial direction by the distance between two tracks on the magnetic tape. To precisely maintain the distances in the axial direction, spacers 39 are used, the thickness of which corresponds to the distance between the tracks and z. B. 0.35 mm. The spacer disks, together with the magnetic heads and their holder, fill the bores 1 to 20 in the carrier 21 and, depending on the position of the head gaps, are inserted in an appropriate number in front of and behind the holding jaws 33, 34 in the axial direction. The in F i g. 5 illustrated magnetic head is intended for. B. scan the track I. Accordingly, in a head wheel with twenty magnetic heads, nineteen spacer disks 39 are located behind the magnetic head. In the following head, a spacer disk is provided in front of the holding jaw 33 and eighteen spacer disks behind the holding jaw 34 , etc., up to the magnetic head 20 for scanning the track XX, in which all nineteen spacer disks 39 are located in front of the holding jaw 35 for scanning track 1I . In addition to the precise position of the head gaps in the axial direction, this results in the advantage that the bores for receiving the magnetic heads are completely filled and there is no imbalance in the rotating head carrier. The ring disk 43 already mentioned forms the end of the bores.

To lead out the coil lines 41 from the head coil 27 are Recesses 40 are provided in the holding jaw 33 and the spacers 39. Farther a groove-shaped cutout 42 is assigned to each bore in the head carrier 21. To the Anyone can finally adjust the angular distances of the magnetic heads Magnetic head with its holder in the bore of the carrier 21 around the center of the bore be twisted.

The transverse tracks I to XX (F i g. 1) are not exactly at right angles to the tape edge 47, because during the recording a transverse track, the magnetic tape is moved by one track width. Although the scan path the magnetic head gap is perpendicular to the tape edge 47, the transverse tracks run somewhat aslant.

This inclination is shown in FIG. 7 for lanes I to VI, for Increased clarity exaggerated, shown. Therefore, if the axis of the head wheel runs in the longitudinal direction of the magnetic tape as in FIG. 6, left, so would the column of the heads z. B. lie on the tracks at the beginning of their scanning movement, however, deviate more and more from the tracks during the scan. According to FIG. 6, right, the axis of the head wheel is therefore diagonally opposite by the same amount the longitudinal direction of the tape to arrange the tracks from the exact transverse position differ.

In this case, however, there are two other errors in the location the sample column. If the gaps are in the direction of the axis of the head wheel, so they are now at an angle to the recording in the tracks, as in FIG. 7 for column 1 and 2 is indicated in comparison to lanes I and 1I. This in However, in practice the misalignment, which is exaggeratedly drawn, is very much small amount. From the scale representation in FIG. 8 emerges; that the misalignment with a gap of 2.5 #t width and 0.25 mm length is negligible. A second Error is caused by the fact that the following magnetic head gap is a little later reaches the beginning of its track than would be required for proper scanning. Both errors can be avoided if, as shown in FIG. 7 for tracks III and IV, the associated head gaps 3 and 4 are parallel when the head wheel is inclined be arranged to the longitudinal direction of the tape. For this it is necessary that the holes for receiving the magnetic heads in the head wheel by the angular amount by the the head carrier is arranged at an angle, are drilled in at an angle. If so desired is to make the head wheel with a smaller diameter, you can use the magnetic heads Arrange them in pairs next to each other on a multi-start helix.

F i g. 9 shows a head wheel, seen in the axial direction, in which twenty Magnetic heads arranged in a double helix on the circumference of the head wheel are. The division of the heads on the circumference of the head wheel is shown schematically in FIG. 10, while FIG. 11 is a side view of the head wheel according to FIG. 9 shows. F i g. 12 is again a section of the magnetic tape 23 on which the twenty Traces for a field are drawn in and shown enlarged. The ones with roman Traces marked with digits are made up of the heads marked with Arabic numerals scanned one after the other in the sequence shown in the figure.

You can go on in this direction and go to FIG. 13 all Arrange magnetic heads on a five-thread spiral. The diameter of the head wheel is thereby further reduced and in this case amounts to for the already mentioned introduced recording methods only about 50 mm. So that the scanning of the twenty tracks of a field is finished again in 1 / so second, the number of revolutions must of the head wheel can be increased accordingly and in this example is 15,000 rpm.

F i g. 13 shows the head wheel and, in the development above it, the arrangement of the head gaps on the circumference of the head wheel. The table on the right shows the order in which heads 1 ... 19 are used to scan coils I. .. XIX be switched on.

In Fig. 14 shows another exemplary embodiment for carrying out the method according to the invention in order to repeatedly scan the picture signal for a television picture or field with the magnetic tape at a standstill. In the exemplary embodiment shown, the head wheel has only four magnetic heads 1 to 4; whose head gaps are distributed at equal angular intervals of 90 ° on the circumference of the head wheel and are arranged along a circumferential line, that is, without mutual offset. The head wheel is thus designed in the same way as the head wheels used for recording the television signal or for scanning the recording when the tape is moving. For the scanning of the twenty tracks of a field when the magnetic tape is stationary, the head wheel is longitudinally displaceable on the shaft 62 driven by the motor 60 in the direction of the arrow 61. The path of the back and forth displacement of the head wheel indicated by the double arrow 63 takes place, for example, as shown in the figure, through an obliquely recessed groove 65 on the circumference of the cylindrical body 64 Slide 66 is attached. The slide is supported by means of a guide so that it can only move in the direction of the axis of rotation of the head wheel, and engages in a groove of a hollow shaft (socket) 68 connected to the head wheel, which is longitudinally displaceable on the drive shaft. The rotating head wheel thus follows the position of the pin 67 in the groove 65. The cylindrical body 64 is driven by the shaft of the head wheel via a reduction gear 69, 70.

To scan the twenty tracks of a field five revolutions of the head wheel with four heads are required. The longitudinal movement of the head wheel in the axial direction is to be controlled in such a way that the following head sweeps over the next following track when the tape is stationary. The rotary body 64 therefore has to perform half a revolution for five revolutions of the head wheel, so that the path 63 of the head wheel is covered in one direction. According to the existing standard, this distance must be covered in a time of 1/5 of a second. The speed of the groove body 64 must therefore be 25 rev / sec. Since the head wheel makes five revolutions during the sampling time of 1/2 second, its speed is 250 rev / sec. The reduction of the gear 69, 70 must therefore be 10: 1 in the selected embodiment.

Compared to the previously discussed embodiments according to FIGS. 2 to 13 have the embodiment according to FIG. 14 has the advantage that, in addition to repeated scanning of the signal for a television picture or field, continuous scanning is possible in the usual manner with the magnetic tape moving, even when the longitudinal displacement of the head wheel is switched off. For this purpose, the periodic longitudinal displacement of the head wheel can be switched off by stopping the groove body 64 . For this purpose, the shaft 72 of the gear wheel 70 is connected to the shaft of the groove body 73 by a releasable coupling 71 . As in the example shown, the coupling can consist of a spiral spring which is pushed onto the two shaft ends, and one spring end is firmly connected to the driven shaft 73. The figure shows the clutch in the uncoupled state. Here, the second elongated spring end 74 rests in the stop which can be displaced by the handle 75. As a result, the spring 71 bends and is no longer taken along by the drive shaft 72. The stop 76 is shifted to the right for engaging the clutch. This releases the extended spring end 74, the spring 71 pulls itself tight on the shaft 72 and takes the shaft 73 with the groove body 64 with it.

The device described above is both for recording a television signal on magnetic tape according to the established method as well as to suitable for scanning the recorded signal while the magnetic tape is running. About that In addition, it offers the possibility of stopping the magnetic tape at any point and to look at the individual image located there with the magnetic tape stationary, in order to e.g. B. select a suitable interface.

In Fig. 16 is 23 the magnetic tape to be cut. 105 and 106 are the magnetic tracks on a storage drum 91 (FIG. 17).

F i g. 17 shows the entire apparatus for cutting a Television magnetic tape.

F i g. 18 shows the section of the drum 85 from FIG. 1 through the center of the axis in direction bb. 17, around which the magnetic tape 23 to be cut, passed over the pulleys 134 and 135, is guided.

For finding the place in which area the cut on the magnetic tape 23 is to take place, the magnetic tape 23 runs at normal speed in the direction from arrow 87. Here, the image is viewed by means of a monitor and the the associated sound was listened to.

For this normal magnetic tape sequence, the switching lever 145, F i g. 17, brought into position 149. As a result, a blocking plate 112 comes into the position shown in dotted lines. With the extension 150 of the switching lever 145 extending beyond the pivot point, the changeover switches 119, 120, 123 and 124 on the amplifiers 95 and 96 are also actuated.

As a result of the rotation of the storage drum 91, which is driven by the shaft 86 of the motor by means of the belt 90, the shaft 101 of the wrap spring clutch 99 comes in front of the locking plate 112 and strikes against it.

The wrap spring 99 is thereby bent open, and the shaft 97 with the magnetic heads 81 attached to it for scanning the audio track 82 and the head 84 for scanning the control track 83 is then decoupled from the shaft 98 and stops.

In this state, the location of which is determined by the locking plate 112, which also acts as a stop, the magnetic heads 81 and 84 are at the point on the magnetic tape, as seen from the image scanning wheel 103 , at which the magnetic head 104 (FIG. 16) the sound was recorded on track 82 of the magnetic tape 23, just as the control pulses were recorded on track 83 by means of magnetic head 138 below.

When the switching lever 145 is in position 149, actuated via the linkage 109 and lever 110, 111, the roller 88 presses the magnetic tape 23 against the shaft end 86 'of the motor 89, and the magnetic tape 23 runs in the direction of arrow 87.

As already mentioned, the magnetic tape 23 is guided around the drum 85 and past the magnetic heads 81 and 84 by means of the deflection rollers 134 and 135. The drum 85 serves as a guide, possibly also as a flywheel, and runs freely around the shaft 97, as shown in FIG. 18, from the center of the axis in direction bb, can be seen.

By moving the blocking plate 112, the switch contact 113 connected to it switches on the extinguishing current from the extinguishing generator 114 for the extinguishing magnet in the magnetic head combination 94. The magnetic head combination 94 also contains the magnetic head for sound recording and recording on the magnetic track 105 and the magnetic head for the control pulse recording and recording on the magnetic track 106 on the storage drum 91.

When the erase head is in operation, both magnetic tracks 105 and 106 are erased at the same time. Of course, these three magnetic heads can also be attached individually to the holder 130. This holder 130, together with the magnetic head combination 94, can be pivoted around the shaft 98 by means of the hand crank 133, worm 132 and worm wheel 131.

This pivoting option is used to, when playing back, after the cut and reconnection of the tape ends, the continuation of the Cutting missing tone and control pulse components in the correct location, in the correct phase and in the exact length from the storage drum 91 and back on the trimmed To dub magnetic tape. A special meaning for the exact fit of the The heart-shaped collector disk 115 is used for this purpose.

As long as the search for the magnetic tape 23 runs normally to a To find the place where a cut is to be made, as long as the Magnetic heads 81 and 84 passing information from tracks 82 (sound) and 83 (control pulses) are scanned and continuously on tracks 105 and 106 of the storage drum 91 transferred.

The path of the voltage induced in the magnetic head 82 (sound) runs during the "Search" operating state described above, with the switches 119, 120, 123 and 124 in notch 149, over the heart-shaped collector disk 115 (FIGS. 17 and 18 ) the pickup pin 1.16 looping over it, the line 118 and the switch 119 to the input E of the amplifier 95 and from the output A of this amplifier via switch 120, line 121 to the magnetic head in 94 for recording on the sound track 105 of the storage drum 91.

At the same time, the one induced in the magnetic head 84 (control pulses) goes Voltage across collector 117 (Figs. 17 and 18), line 122 and the switch 123 to the input E of the amplifier 96 and from the output A of this amplifier via switches 124, line 125 from magnetic head in 94 for recording on control track 106 of FIG Storage drum 91.

During the search process, loudspeaker 128 decoupled from output A of amplifier 95 via amplifier 1.27 enables eavesdropping and, in the same way, cathode ray oscilloscope 144 connected to output A of amplifier 96 monitors the control pulses. Instead of the oscilloscope 144 , however, a second loudspeaker can also be provided in its place.

Another control option is the use of a level meter, via which, of course, decoupled, e.g. B. both outputs A of the amplifier 95 and 96 are connected.

If now. either visible via the image monitor or audible via loudspeaker 128, that part of the magnetic tape runs into the area around the drum 85 in the area of which a cut is to be made, then the switching lever 145 is brought into position 147. At the same moment the roller 88 lifts off the motor shaft 86 and the magnetic tape 23 stops. The magnetic tape 23 is also held by a rocker 140 on the lever 110, which presses the magnetic tape 23 against the two deflection rollers 134 and 135. The rocker 140 is curved and protrudes with the ends resting on the deflection rollers 134 and 135 beyond the axes of the circumferential rollers, so that the part of the magnetic tape guided around the drum 91 is tensioned around the drum.

When the switching lever 145 is moved into the position 147 or 148, the locking plate 112 is withdrawn via a linkage 109 and the double lever 142 articulated to it at the same time as the stiliset coffin of the magnetic tape run-off. This opens the contact 113, whereby the extinguishing magnet in the combination head 94. a ;: ßer operation comes. At the same moment, the wrap spring clutch 99 clamps on the shaft 98, and the two magnetic heads 81 and 84 on the shaft 97 come into circulation with the latter in the direction of arrow 141. The tracks 82 (sound) and 83 (control pulses) of the magnetic tape 23 now fixed with drum 85 are scanned by the magnetic heads 81 and 84 in the same way as before when the magnetic tape 23 with drum 85 ran in the direction of arrows 87 and 143 and the magnetic heads 81 and 84 were stationary.

In this operating state of the device, in which the switching lever 145 is in position 147 or 148, the switches 119, 120, 123 and 124 on the amplifiers 95 and 96 are also switched accordingly, and it can be seen that the outputs A of both Amplifiers are no longer connected to a magnetic head. If this were still the case, there was either another transfer from magnetic tape 23 to storage drum 91 (position of switch lever 145 in position 149) or another transfer from storage drum 91 to magnetic tape 23 (position of switch lever 145 in position 146). As it is, however, the same information content is now on the storage drum 91 on the tracks 82 and 83 of the part of the magnetic tape 23 located around the drum 85. This should be achieved for the cutting in this area of the magnetic tape 23.

You can now begin narrowing down the interface. This can be done as follows. At the time of searching, the pickup pin 116 (Figs. 17 and 18) rubs on the inner circular ring surface 14 of the collector disk 115. The entire track 82 (sound) from the magnetic head 81 and also the entire track 83 (control signal) from the magnetic head 84 scanned which tracks are located on the part of the magnetic tape that wraps around the drum 85 , irrespective of the location of the drum circumference at which the pick-up pin 116 is located.

If the pick-up pin 116 is now in its holder 136, as in FIG. 18 drawn, z. B. pushed onto the circular ring surface 7, then only the length of the tracks 82 and 83 on the magnetic tape 23 is scanned, which are on the circumference within the angle whose legs from the center of the axis 97 from the circular segment surface of the circular ring 7 on both sides of the heart-shaped Tangent collector plate 115 . For the assumed example, this is an angle of approximately 90 °, which is between 135 and 225 ° within the drawn-in degree division of FIG. 18 lies. This useful waste traverse length can be further concentrated, if the follower pin 116 (F i g. 18 and 19) is even further shifted up to the Kreisringfiäche 1 on the collector disc 115.

There is thus the possibility of localizing this letter from the information content of the sound track 82 of the magnetic tape part lying around the drum and standing up to a single letter from a word so that only it can be heard in the loudspeaker 128 alone.

However, the delimitation of the relevant information part found via the heart-shaped collector disk 115 by rotating the pick-up pin holder 136 at any point on the stationary magnetic tape 23 around the drum 25 can be erased. For this purpose, only the switch 129 on the erasing current generator 114 needs to be switched to the line 150 , whereupon the erasing current flows through the magnetic head 81 and the found and narrowed point on the audio track 82 is erased with one or more head overflows. Whether this is the case can be audibly checked immediately by switching the switch 129 back to the line 118 . Then, of course, nothing can be heard with loudspeaker 128. In practice you can use a z. B. re-insert deleted letters or a word or replace it with another letter or word.

For this purpose, the information transferred to the storage drum 91 during the search is now listened to by moving the switch lever 145 from position 148 to position 147 . Now the magnetic head (sound) of the head combination 94 is connected to the input E of the amplifier 95 via line 121 , and the loudspeaker 128 is, as can be seen, still connected to the amplifier output A via output A and switch 120, despite the switchover 105 with that of track 82 and if toggle switch 145 is switched back and forth from position 147 to position 148 , this switchover can take place in such a way that what is deleted on track 82 from track 105 can be faded in.

With the above-described example of searching, locating and delimiting an interface, it was explained how a certain area is deleted from a part of the track 82 (sound) on magnetic tape 23 and how the same can be added again from the storage drum 21. It was assumed that when comparing the recording of track 82 (sound) on magnetic tape 23 and track 105 (sound) on storage drum 91 by alternately moving the switch lever 145 from position 147 to position 148, the information content of both tracks coincide. But it may also be that this is not the case, especially z. B. after a cut and the reconnection of the tape ends or if the magnetic tape had to be removed from the drum for some other reason or because the information transferred from the magnetic tape 23 to the storage drum is faded into the track of another magnetic tape on the same device shall be. In any case, the magnetic tape must be removed from the drum 85 in order to glue the ends of the tape together seamlessly. If the ends are reconnected and the magnetic tape is again wrapped around drum 91 , the remainder of the information in track 82 (sound) is undoubtedly on track ZQ (FIG. 16) compared to the same information ZQ in track 105 the storage drum 91 displaced, as shown in FIG. 16 can be seen. Here, magnetic head 81 is located between Q and R and magnetic head combination 94 between T and U of the same information content on tracks 82 and 105. Coincidence can now be brought about again by turning the hand crank 133 over worm 132, worm wheel 131 with holder 130 and moving the magnetic head combination 94 over track 105 until 94 is also between Q and R on this track 105, so that the congruence of the two tracks 82 and 105 is restored.

Since the switches 119, 120, 123 and 124 on the amplifiers 95 and 96 are coupled to one another and to the shift lever 145, as already described is also the congruence of the control pulses by means of an oscilloscope 144 verifiable, and because the magnetic gaps of the magnetic heads 81 and 84 are exactly aligned and also the column of the write heads in 94, is how from the location of these magnetic heads in Fig. 16 recognizable, ensures that up to the accuracy of the congruence equality of the cutting pulses on tracks 83 and 106 the status of the information content of Magnetic tape and storage drum can be brought back into alignment.

To carry out the exact cut via a cutting pulse, e.g. B. at 102, the cut must be made at the level of the previous location of magnetic head 104 . This location is indicated by the dot-dash line 137 for magnetic tape 23 around drum 85. The holder 136 with the stripping pin 116 is pivoted to this location for cutting. Then a device, not shown, with a vertically displaceable knife, e.g. B. a razor blade, can be plugged onto the holder 136. The scanning of the individual image by means of the head wheel 103 shows the image in the monitor which belongs to the sound displaced up to this point. The cutting pulse 102 indicates the exact location of the image line and the knife blade is then drawn over this with its cutting edge to cut the magnetic tape 23. The remaining tape ends are then connected.

The information content of the track 82 stored on drum 91 is then brought into congruence with the remainder on magnetic tape 23. B. is not necessary to look at the picture. In addition, the playback of the information from drum memory 91 on tape 23 is limited to the length of the gap on the magnetic tape. This is done by moving the pick-up pin 116 (FIGS. 16 and 18, below) in its holder 136 over one of the circular ring sectors 1 ... 14 of the collector disk 115, which approximately corresponds to this length.

Then, through examination and precise adjustment, the congruence is established of the control and cutting pulses on tracks 83 and 106. Possibly is a slight adjustment is required, which can be achieved by appropriate placement of the combination magnetic head 94 is carried out by turning the hand crank 133.

After that, the copying of the data masked out by means of the collector disk 115 can be performed Information from the track 105 (sound) of the drum memory 91 to the Information gap begin in track 82 (sound) of the magnetic tape. Shift lever is used for execution: 145 brought to position 146. As can be seen, then traces 94 track 105 as a read head because line 121 is at input E of amplifier 95, and over Line 118 is the magnetic head 81 ah write head to the output A of the amplifier 95 connected. It is not necessary to play back the control pulses from track 106, which is why it is used to connect the magnetic heads in position 146 of the switching lever 145 to the amplifier 96 there are no connecting lines.

A subsequent check to verify that the dubbing succeeded, completes the cutting process.

A completely different design embodiment of the device for Finding, locating and isolating an interface in video magnetic tapes shows Fig. 19th

The special feature of this facility is that in the tape drum of the drum storage is included. In contrast to the execution according to FIG. 17 the sound and / or control information is stored not on the inner wall surface of a drum that can rotate on its own, but on the inner wall surface 152 of the tape drum 185, which is covered by the video magnetic tape 23 is wrapped around.

For writing and reading the information (sound) stored on the inner drum surface 152 serves as in FIG. 17 on the drum 91 z. B. a magnetic head combination 194. The reading and writing from and to the magnetic tape 32 are likewise carried out by means of a magnetic head 181.

In detail, the parts act to transport the magnetic tape 23 in in the following way: The device is driven in the exemplary embodiment F i g shown. 19 by the Synehronmotor 155 with z. B. the speed of 60 rpm. This gives one for drum 185 at 40 cm tape speed per second Diameter of 127.8 mm.

The motor 155 is connected to its shaft 186 via the wrap spring clutch 199 releasably connected to the transmission shaft 156 of the differential gear. With this Fixedly connected to shaft 156 is the first sun gear 157. The transmission gears are preferably designed as spur gears. Accordingly, there is the differential gear from the sun gear 157, the planet gears 158, 159 engaging in this which engaging the planet gears 160, 161 to transmit the torque make the second sun gear 162.

The axle bolts of the planet gears 158 to 161 are in pairs on the opposing walls 163 and 164 of the cylindrical planetary gear housing 165 attached. The housing 165 is housed in a further cylindrical housing 166, and both housings are rotatable about the same axis.

On the outer circumference of the planetary gear housing 165, a ring gear 167 is provided, which meshes with a gear 168 with a gear ratio of 1: 2. The gear 168 with a further gear 170 sits on a shaft 169, and the bearing 171 of this shaft is located on the housing 166, around the outer circumference of which the worm gear ring 172 is arranged. Gear 170 finally meshes with a gear 173 with a gear ratio of 1: 1. The drum 185 is firmly connected to this gear 173 via a hollow axle. Another hollow axle 174 is inserted through this hollow axle, on which the sun gear 162, the brake disc 175a and above the flywheel 176 are arranged. The magnetic head 181 is attached to the edge of the flywheel. Combination magnetic head 194 is expediently pivotable on a lever 177 and is pressed against the inner edge 152 of the drum 185 by means of a spring 178.

The combination head 194 rotates with magnetic head 181, but can opposite this can still be pivoted. Furthermore sits on the flywheel 176 of the Collector with the heart-shaped collector disc 115 and a slip ring collector 178.

The hollow shafts carrying the flywheel 176 and the drum 185 are mounted on the shaft shaft 179, which is on the one hand on the support block 192, as shown in FIG. 17, is fastened with one end of the cone and, on the other hand, is guided and supported in the shaft 156. The central bearing 180 of the hollow shafts is located in the table top 181, on which the entire device is mounted. The holder 136 with the pick-up pin 116 is also pivotably located on the support block 192 , as is the case with the device according to FIG. 17 are present.

For the device according to FIG. 20 there are when engine 155 is running, the following operating positions: 1. Shift lever 145 'in position I In this position The locking plate 189 lies in the way of the shaft 190 of the wrap spring clutch 199. Thus if the spring 199 bends when the shaft 190 hits the locking plate 189, and the motor shaft 186 is decoupled from the transmission shaft 156. The whole facility is not in operation, except for motor 155.

2. Shift lever 145 'in position III The locking plate 189 is brought into the dot-dash position via linkage 191 and lever 193, and the brake disc 175b is then held in place via lever 195 and brake shoe 196, and the planetary gear housing 165 is thus also fixed. In addition, the housing 166 with the worm gear ring 172 located around it is held in place in that the worm 183 engages in the toothing of 172. The bearing 171 of the gears 168, 170 is also fixed with the housing 166.

Taken by the wrap spring clutch 199, the sun gear 157 now rotates in the direction of the dotted arrows 184.

If the direction of the arrows 184 is counter-clockwise, the planet gears 158, 159 run to the right, the engaging planet gears 160, 161 to the left, as they revolve around their axle bolts, which are attached to the planetary gear housing 165 and this housing 165 as a result of the braking is now established (position shown) because it is stopped by the brake shoe 196 resting on disk 175 b.

The planet gears 160, 161 engaging in the sun gear 162 now drive this sun gear to rotate clockwise. This means that the flywheel 176 connected to 162 also rotates with the magnetic heads 181 and 194 in the same way. During their rotation, the magnetic tape 23 lying around the drum 185 and the inner wall surface 152 of the drum 185 are continuously scanned. This is the operating position during which the interface is localized by pivoting the holder 136 and delimited by pulling the pick-up pin 188 forward, as has already been done with FIG. 17 was operated.

If, however, the desired cutting area is not yet correctly accumulated on the magnetic tape located around the drum 185 , the magnetic tape 23 can be fetched forwards or backwards with rotating magnetic heads by turning the hand crank 204 counterclockwise or clockwise.

Correspondingly, the housing 166 is pivoted with the ring gear 172 by means of the worm 183. In this case, the gearwheel 168 then rolls around the gear rim 167 , as a result of which the drum 185 then rotates forwards or backwards. With each revolution of the drum 185 , a length of 40 cm of magnetic tape is transported, which can be listened to again so that the cutting area can also be found by means of the hand crank. If the switch lever is in position 1I, this is the position for searching for a cutting area over a longer length of magnetic tape.

In this case, the brake shoe 196 is free and does not touch the brake disks 175 a, 175 b . The drum 185 with magnetic tape 23 is now put into operation by pressing the button 197 , or by pressing the button 198 the swing path with the magnetic heads 181 and 194 revolves. The gear parts that come into effect are marked in their direction of rotation by arrows drawn in the same way. Pressing the button 197 means that the drum 185 is now rotating, because the flywheel 176 with the magnetic heads is stopped via the brake shoe 199 via the brake disk 175a.

If key 198 is pressed, the magnetic heads 181 and 194 rotate and the drum 185 stands still. In any case, however, the differential gear has a balancing effect so that no pitch fluctuation occurs because the scanning speed between the magnetic heads and the magnetic tape always remains constant.

When the searched magnetic tape area comes around the drum 185 when searching with a motor drive, the switch lever 145 'is brought into position III, whereby, as already described, the drum 185 with magnetic tape 23 is stopped and the flywheel 176 with the magnetic heads starts to rotate.

If the interface is delimited, the cutting device 200 is attached to the holder 136 , or it is already attached, and the knife 201 (FIG. 18) with its holder 202 is pulled into the position 203 shown in dashed lines for the vertical tape cut.

It is with the device according to FIG. 19 also possible to save the control impulses. To scan the control track from tape 23 onwards, the magnet 187 required for this is fixedly arranged on the drum circumference at 137. It should be apparent that there are still a few variants for operating and using the devices described. It should not be forgotten that it can of course also be used to cut video magnetic tapes in which the image track runs diagonally across the tape.

So that now, after the cut of the tape and the reconnection of the tape ends, also in the case of the device according to FIG. 19 shows the continuation of the tone and control pulse component omitted by the cutting in the correct location, in the correct phase and in the exact length from the storage on the inner surface 152 of drum 185 as in the device according to FIG. 17 is to be played over by drum 91, the magnetic head combination 194 must also be pivotable with respect to magnetic head 181 or 187.

But because 184 revolves with 181, it is difficult to swivel using the handwheel. This is used in the device according to FIG. 19 now a device which is provided on the bracket 192, at 204 (FIGS. 18 and 19) and has the following function: The magnetic head combination 194 is attached to a disk 205, on the circumference of which there is a ring gear which is in the Height of 194 is interrupted.

The disk 205, for its part, is mounted on the flywheel 176 so that it can pivot about the common center of the axis. A gear 206, the shaft of which has its bearing in the flywheel 176, engages in the ring gear on the disk 205 , and another gear 207 is located on the shaft above the flywheel 176.

When the flywheel 176 is at a standstill, rotating the Gear 207, the magnetic head combination 194 relative to the magnetic head 181 is pivoted will. This pivoting now takes place when the entire system rotates (centrifugal mass 176 and disk 205) in that the two opposing tooth segments provided bridge 209 by means of adjusting knob 208 from position V to the positions IV or VI is moved by the bracket 192.

When the flywheel 176 rotates, the gear wheel 207 passes under the bridge 209 and when the setting knob 208 is in position V, as shown, the passage is free. Is z. If, for example, the setting knob is brought into position IV, the right tooth segment on bridge 209 comes into the way of gear wheel 207, and the teeth of the tooth segment mesh with gear wheel 207 and rotate it during the short period of engagement.

As long as the possibility of combing in a tooth segment on the bridge 209 exists in gear 207, this becomes with each complete revolution of the flywheel 176 twisted by a certain distance.

As a result, disk 205 and with it the head combination 194 around the center of the axis, relative to the rotation of the flywheel 176, experience an additional twist, which depends on the number of teeth in the toothed segment and the transmission ratios between the ring gear on disk 205, gearwheel 206 and the number of teeth Gear 207 can be selected so that the pivoting of magnetic head combination 194 z. B. corresponds to the distance between two stored control pulses on the magnetic layer on the inner surface of drum 185 .

However, this distance could also be that of two cutting pulses which are identical to the image lines.

If the setting button 208 placed with the toothed segment bridge 209 in position VI, then the left toothed segment to bridge 209 meshes with a at each revolution of the flywheel 176 in gear 207th Gear 207 is then carried along in the opposite direction.

Claims (13)

Claims: 1. A method for scanning the on a television magnetic tape Image information stored in parallel transverse tracks and / or in a longitudinal track associated sound information recorded on the magnetic tape by means of a rotating Magnetic heads arranged on a carrier, characterized in that for recovery of the image signal the magnetic heads transversely to the track direction against each other by the track width offset one after the other in the direction of the track with the same peripheral speed as the Recording heads repeatedly over the one containing a television picture or field Moving pieces of the stationary magnetic tape and those supplied by the individual heads Signals are forwarded in a cyclical order and become a periodically repeating one Television signal are composed and / or to recover the audio signal Magnetic head on the sound track is moved in such a way that the sum of the peripheral speed of the head gap and tape speed constant and equal to the tape speed when recording is. 2. Device for performing the method according to claim 1, characterized in that the number of magnetic heads to recover the image signal on the rotating carrier is the same as the number of transverse tracks that one complete television picture or field included, and that the header column with under equal angular distances in a helical line on the circumference of the rotating Head carriers are arranged. 3. Device according to claim 2, characterized in that that the head gaps are arranged on a single-thread helix. 4. Establishment according to claim 2, characterized in that the head gap is on a multi-thread Helical lines are arranged. 5. Device according to claims 2 to 4, characterized characterized in that to determine the position of the heads in the axial direction of the rotating Head support spacers are used, the thickness of which corresponds to the distance between neighboring Cross tracks corresponds. 6. Device for performing the method according to claim 1, characterized in that for the recovery of the image signal of the head carrier with the heads arranged along a circumferential line in addition to the rotary movement executes reciprocating movement in the axial direction of the carrier. 7. Establishment for carrying out the method according to claim 1, characterized in that for Recovery of the sound information the magnetic tape wraps around a drum and the Sound track is scanned by a magnetic head on a rotating head carrier. B. Device according to claim 7, characterized by a coupling with which either the rotating head carrier when the drum is stationary or the drum when it is stationary Head can be driven. 9. Device according to claim 7, characterized by a differential gear between drum and head carrier, through which the relative speed between head and audio track is kept constant regardless of the tape advance. 10. Device according to Claims 7 to 9, characterized in that the acceptance of the sound signal delivered by the head is carried out by means of a sliding contact, whose with the head support circumferential part is shaped such that when moving of the fixed part is the duration of the signal taken with each revolution changes. 11. Device for performing the method according to claim 1, characterized characterized in that the means for picking up the image signal and the audio signal are arranged with respect to the magnetic tape so that that of the sound scanner The sound signal supplied corresponds to the television picture obtained by the image scanning device the associated tone. 12. Device according to claim 7, characterized in that that a further drum is detachably coupled to the drum, which preferably a magnetic layer serving as an intermediate storage device on its inner surface wearing. 13. Device according to claim 7, characterized in that the intermediate memory by a magnetic layer on the inner surface of the wrapped by the magnetic tape Drum is formed. Publications Considered: British Patents No. 894 991, 859 783; "Kino-Technik", 1955, pp. 84 and 86.