FR2483662A1 - RECORDING OR RETURN SYSTEM ON A HELICOIDAL TAPE - Google Patents

Abstract

A description is given of a spiral-scanning tape recording and/or playback system of the type in which a scanner (12) is used for the track scanning of information which is recorded in every track at an azimuth angle with respect to the transverse direction over the tape, the azimuth angle for each track being different from the azimuth angle of the neighbouring tracks in order to avoid crosstalk between tracks without any need for spacing bands between the tracks. In this case, the tape tracks are scanned from virtually the same point on the cylindrical surface of the scanner.

Description

 In recording systems where information is recorded on adjacent tracks, crosstalk between tracks poses a problem when the restitution tests move poorly. One attempt to resolve these problems has been to use a dead space or guard strip of a certain minimum width between adjacent tracks. However, when using guard strips, more recording medium is required to record the information. and it is necessary to provide in the recording and / or restitution system, the additional quantity of recording medium, it is therefore necessary to incorporate a larger cassette. To avoid crosstalk without using a guard tape, recording techniques Azimuth angles are commonly used in recorders. With these techniques, the adjacent tracks are explored by separate transducers, the spaces of which are angularly oriented in different directions relative to the transverse direction across the tracks. However, most of the current recorders are of the tape type hdlico $ dale and the separate transducers used in azimuth angle recording are spaced around the circumference of the explorer or rotary scanner on its cylindrical surface.

In a well-known video recorder, the hdlicoSdale scanning arrangement has two transducers having different azimuth angles and these transducers are spaced 1800 apart around the circumference of the scanner. During recording or playback modes, each transducer scans a television frame (262.5 horizontal lines in NTSC systems) for each revolution of the scanner, thus successive frames are recorded or played back from adjacent tracks on the tape having different azimuth angles. Consequently1 the circumference of the scanner in such recorders must be equal to the scanning length of two frames. This is double the circumference of the scanner of recorders using guard bands between adjacent tracks and which explore a frame. television in a track during each scan of the scanner having only one transducer arranged in one location.

 According to a preferred embodiment of the invention, the azimuth angle recording is accomplished in a helical scanning tape recorder with adjacent tracks which are scanned from a substantially common location on the cylindrical surface of the scanner.

In one embodiment, the orientation of unsS transducer space is alternately changed during successive rotations of the scanner and in another embodiment, each azimuth angle space is incorporated on a separate transducer with spaces that are individually validated in sequence during successive rotations of the scanner0
The invention will be better understood and other objects, characteristics, details and advantages thereof will appear more clearly during the explanatory description which follows, made with reference to the appended schematic drawings given solely by way of example illustrating several modes. of the invention and in which
- Figure 1 shows a compact arrangement of exploration on tape in a recording and / or playback system with helical exploration
- Figure 2 shows a tape format with hdlicoidale exploration where guard bands are arranged between adjacent tracks to avoid crosstalk
- Figure 3 shows a tape format with helical scanning where an azimuth angle recording technique is used to avoid crosstalk without having guard bands between adjacent tracks
- Figure 4 shows an embodiment of the invention where the orientation of a single transducer space is changed to change its azimuth angle for each successive rotation of the scanner; and
FIG. 5 shows another embodiment of the invention where each azimuthal angle space is incorporated on a separate transducer, these spaces being individually validated in sequence during successive rotations of the scanner.

The arrangement of exploration on tape of the compact type of FIG. 1 is taken in a known video recording and / or reproduction system with helical exploration and a magnetic tape 10 is guided in a loop around the cylindrical part of a scanner 12 which rotates to explore each frame of video information on a separate track from the strip with a guard strip arranged between adjacent tracks as can be seen in FIG. 2 where the guard strips are indicated by dotted lines
Guides 14 and 16 of the strip are arranged to direct the strip 1Q in and out of the loop, this strip 10 entering the loop from a source (not shown) and passing to a storage (not shown) where it departs from the loop. To allow the scanner 12 to have a compact dimension, the loop of the strip extends there over almost 360 in an omega configuration, and a single transducer space 18 explores the tracks individually from a location on the cylindrical surface of the scanner 12. The height of the strip 10 on the cylindrical surface of the scanner 12 differs between the start and the end of the loop, so the loop is of helical configuration and the tracks are explored across the width of the strip at an angle by relative to the direction of travel of the strip.

 Although the exploration arrangement of Figure 1 is very compact, crosstalk can be avoided by placing guard bands between adjacent tracks as shown in Figure 2. However, the guard bands occupy considerable space on the tape and therefore more tape is needed to record a given amount of information. Consequently, the power supply and storage capacities of the tape must be greater when using guard tapes and the general dimension of the recording and / or restitution system has to be increased accordingly. compact recording and / or restitution if the exploration arrangement of the tape of FIG. 1 can between modifies to explore the information tracks for an azimuthal angle recording technique, thus avoiding crosstalk between adjacent tracks without using a guard strip. Figure 3 shows the herringbone or herringbone format resulting from this azimuth angle recording technique, and the present invention provides a transducer means for exploring tracks adjacent to such azimuth angle formats from a substantially common location on the cylindrical surface of the scanner 12 in the compact arrangement of Figure 1.

Figure 4 shows a preferred embodiment of the transducer exploration means, where the position of a single transducer space is changed as shown in dotted lines; to obtain all the azimuth angles required for the desired format of the 2nd band. In this embodiment, the only space 20 on the cylindrical surface of the scanner 12 rotates about an axis perpendicular to the cylindrical surface by an orientation means 22 to place the transducer space 20 in order to change its azimuth angle for successive turns of the scanner 12.

Any suitable electromechanical means 24 for locating the transducer space 20 may be useful6, such as a piezoelectric or bimorph device. To explore individually the tracks of the format of FIG. 3 during successive turns of the scanner 12, the orientation means 22 comprises a rocker or flip-flop 26 at the input of which is applied a traditionally available pulse for exploring a times for a ride. The signal at the output of the flip-flop 26 is applied to attack the electromechanical means 24.

Consequently, each exploration pulse for a revolution changes the output level of the flip-flop 26 and the electromechanical means 24 is attacked by a slot and alternately places the transducer space 20 at an azimuth angle orientation for the even numbered revolutions. from scanner 12 and another azimuth angle orientation for the odd-numbered turns of scanner 12. The slot produced by flip-flop 26 can title recorded on a control track which can then be used during restitution to guarantee that the transducer space 20 will explore each track at the correct azimuthal angle. Of course, those skilled in the art will note, without further explanation, that certain recording techniques on azimuth angle may require that the transducer space 20 can be placed more of two orientations and that the exploration means with transducer of FIG. 4 can between easily be modified for such techniques.

Figure 5 shows another preferred embodiment of the transducer exploration means. In this embodiment, individual 20t and 20 "transducer spaces for each azimuth angle orientation are arranged on the cylindrical surface of the scaeer 12 an tandem along the direction of exploration. A control means 28 is also incorporated to individually validate the transducer spaces 20 'and 20 "to change the azimuth angle for successive rotations of the scanner 12. Any suitable switching means 30 to individually activate the windings traditionally associated with the transducer spaces 20' and 2.8 may be used , like a toggle switch for the track format of FIG. 3. In addition, provision may be made to incorporate, in the cosmutatlon means 30, a means for short-circuiting the windings associated with the spaces transducers 20 'and 20 "when they are not validated during the recording mode. To explore the tracks of the format of figure 3 individually during successive turns fs of the scanner 12, the control means U e 28 comprises a rocker 32 to which is applied the traditional exploration pulse of once per turn, at its entry. The signal at the output of flip-flop 32 is applied to drive the switching means 30. Consequently, each exploration pulse once per turn changes the output level of flip-flop 32 and the switching means 30 is attacked by a slot and alternately validates the conductive space 20 'for the even number turns of the scanner 12 and the transducer space 20 "for the odd number turns of the scanner 12. As the transducer spaces are arranged on the cylindrical surface of the scanner 12 in tandem along the direction of exploration, one transducer space will be ahead of the other during each revolution of the scanner 12. Consequently, the phase relationship between each transducer space and the exploration pulse a times per turn is different, which causes loss of information during recording and playback modes and poses a problem especially in video recording and / or playback systems. This difference in phase relationship can be overcome by delaying the information to the leading transducer space during recording and by delaying the information from the rear transducer space during playback. Of course, those skilled in the art will note without further explanation that more than two transducer spaces can be incorporated into the scanning means of Figure 5, if required, for particular techniques of recording on an azimuth angle. .

 Of course, the invention is in no way limited to the embodiments described and shown which have been given only by way of example. In particular, it includes all the means constituting technical equivalents of the means described as well as their combinations if these are executed according to its spirit and implemented within the framework of protection as claimed.

Claims (7)

 1. Recording or playback system on helical scanning # type tape where a scanner rotates to explore the tracks of information which is recorded in each track at an azimuth angle relative to a transverse direction through said track , the azimuth angle of each track being different from the azimuth angle of adjacent tracks to avoid crosstalk between the tracks without using a guard strip between them, characterized by a transducer means (20, 22; 20 ', 20 ", 28) to explore adjacent tracks of the strip from a substantially commuted location on the cylindrical surface of the scanner (12).  2. System according to claim 1, characterized in that the aforementioned transducer means (20, 22) c # carries a single space (20) and an orientation means (22) for placing said space to change its azisutal angRe for successive turns of the scanner. 3. System according to claim 2, characterized in that an exploration pulse at once per revolution is available and in that the above-mentioned orientation means (22) comprises a rocker (26) at the entry of # which said pulse is applied, the output signal from said rocker being applied to drive an electromechanical means (24) for rotating said space around an axis perpendicular to the cylindrical surface of said scanner, said space (20) being alternately placed by said electromechanical means (24) at an azimuthal angle orientation when the output of said flip-flop (26) is high and at another azimuthal angle orientation when the output of said flip-flop (26) is low, in order to explore a herring level on the strip.  4. System according to claim 3, characterized in that the above electromechanical means (24) comprises a piezoelectric device.  5. Système.selon claim 3, characterized in that the electromechanical means (24) above comprises a bimorph device. 6. System according to claim 1, characterized in that the aforementioned transducer means (20 ', 20n, 28) comprises a separate space (20', 20 ") for each azimuthal angle used and a control means (28) for validating said spaces individually to change the azimuth angle for successive turns of the aforementioned scanner (12).  7. System according to claim 6, characterized in that an exploration pulse at once per revolution is available and in that the aforementioned control means (28) comprises a rocker (32) at the entrance of which is applied said pulse, the output signal of said rocker being applied to attack a means of -cow = ntation (30) to activate individually windings associated with each space in order to validate alternately these spaces by deriving an azimuthal angle orientation when the output of said flip-flop (32) is high and another orientation when the output of said flip-flop is low in order to explore on the strip (10) a herringbone format.