NO135493B - - Google Patents

Description

The present invention relates to an improved control device for recording and playback systems of the transverse type. It is previously known to compensate for incorrect track setting for the tracks that contain the signal information at the scanning transducers when the incorrect control is due to variations in tension and thus the extension of the recording medium over a supporting control surface.

Various signal recording and playback systems are known in which a magnetic tape or other elongated recording medium is made to follow a path over the circumference of a drum-like construction/ usually a cylinder, and where one or more devices for signal recording or playback are present. Such systems are then referred to as inclined track systems. The band can completely enclose the said construction so that the band lies over 360° or more. Alternatively, an open loop can also be used with the ribbon lying inside

a path around only part of the structure's perimeter. As an example, band envelopes of approximately 270°, 180° or 90° can be mentioned which have been obtained in this way.

The devices, for recording and playback, which can

be magnetic heads, are made to rotate at a controlled speed and in a fixed plane at an angle to the direction in which the tape is driven. A screw angle or scanning angle is thus obtained between the rotating devices for recording and playback and the tape's direction of movement. The angle is controlled by the width of the band and by the diameter of the structure that supports the band. Each recording/playback device will scan the tape diagonally across its width. By properly choosing such factors as the number and distance between recording devices used, the screw angle of the tape, the speed of the tape and the rotational speed of the devices for recording and playback, the aforementioned devices can be brought to scan at a desired angle diagonally from one edge of the tape to the other or over only a specific part of the tape, eg half the width of the tape A signal fed to the recording/playback devices is recorded and can be played back from a series of parallel paths of equal length each extending in the same angle across the width of the band.

In recording/playback systems as explained above, there is a preferred tightening of the recording medium when it moves in a path past the scanning recording/playback devices. This tightening determines the actual position the tape takes in relation to the scanning transducer devices. In order to

to be able to play a signal from the recorded tracks on the tape, it is desirable that the stretch over the recorded track length is the same during playback as it was during recording. If these conditions are not met during playback, the recording/playback devices will not be set correctly in relation to the set tracks.

In previously known systems where oblique scanning is used, a stationary transducer head is used to produce a further signal track which is called a control track and which extends longitudinally along the length of the recording medium. When recording oblique information tracks, a signal whose value indicates the speed of the rotating recording/playback devices is recorded as a control track. During playback, the signals in the control track are used as a reference for controlling the speed of the rotating recording/playback devices for the information signal, and these devices are usually referred to as main wheels.

In most existing systems with oblique scanning, the transducers that record and play the control track are located at a part of the tape that is in front of or follows the drum surface that contains them. rotating signal transducers that follow over the inclined tracks. With such an arrangement of the head for the control track, if the tape-shaped recording medium stretches or gets a different voltage during playback than it had when recording, the head wheel belonging to the control signal track will cause the rotating signal transducers not to follow the inclined tracks. This means that one will get a track error during the entire passage of the inclined track due to incorrect setting of the rotary signal transducers and the inclined track from which it is to be played.

Other undesirable conditions relating to the setting of the control track transducer in relation to the area where the inclined tracks are passed by the rotating signal transducers are previously known. E.g. a slight fluctuation of the tape during its run will lead to a time delay between the information signals obtained by scanning the inclined paths and the signal from the guide track transducer which is at a different distance. It is previously known with such devices that the greater the distance between the drum that has the rotating information transducers and the stationary control track head, the greater the time delay will be between the reproduced information signals and the reproduced control track signal.

Because of the time-delay phenomenon, some known systems have provided for placing the control trackhead and information signal transducers in corresponding fluctuations or oscillations by positioning the control trackhead to interact with the tape at the geometric center or midpoint of the portion of the tape surrounding the scanning drum of the tape with the information transducers.

Although the previously known control track device may be appropriate, with the present invention an improved control track transducer device has been arrived at which is more advantageous when it comes to correcting wrong track setting due to variations in stretch and extension of the tape between recording and playback.

The invention thus relates to a device for controlling tapes in tape players, where the tape is transported by friction over a cylindrical tape control surface in cooperation with a rotating signal transducer along paths that extend across the tape's direction of movement, where the tape transport device sets up a predetermined stretch in the tape at its inlet port on the belt guide surface, and with a significantly greater value for the stretch at the outlet point of the belt on the said surface determined by the extent of the belt path on the guide surface and the friction ratio between the belt and the surface, in order to thereby produce a specific stretching of the belt on the said surface, and where a stationary signal transducer for transforming control information along the length of the belt is arranged to control the stretching of the belt, which stationary transducer is arranged to cooperate with the belt at an intermediate point between the inlet and outlet points on the surface, and it is in the essential characteristic in that the position for it intermediate point is such that the stretching that occurs in the part of the band that lies between the inlet point and the said intermediate point essentially corresponds to the magnitude of the stretching of the part of the band that lies between the said outlet point and the intermediate point, since the angular position Øp for the stationary signal transducer (control track head 18) for control information measured from the aforementioned inlet point, is determined by the equation:

where 0 is the wrapping angle of the belt around the belt guide surface and y is the coefficient of friction between the belt and the surface.

The invention will be explained in more detail below

with reference to the drawings in which:

Fig. la and b show, respectively, seen from above and from the side, a recording/playback device made according to the invention,

fig. 2 schematically shows a system for using the control signal device according to the invention for recording and playback,

fig. 3-7 are simplified drawings that further explain the invention and

fig. 8 and 9 show alternative embodiments seen from above, for the use of a control transducer, according to the invention.

In fig. 1 shows, in as simple a form as possible, a device for a recording/playback system of the type which has j oblique scanning. In fig. 1, a recording medium, such as a magnetic tape 2, is placed around the circumference of a stationary cylinder or drum 4. In the usual way, a rotatable transducer 6 is arranged for

to scan the tape 2 through a slit which is inclined in relation to the direction of movement of the tape 2. The tape 2 is pulled around the surface of the drum 4 by means of a device, e.g. a drive roller 10 and a pinch roller 12 in combination. Appropriate spools on which the tape rolls off and on are not shown, but are used for handling the tape 2. In fig. 1, the belt 2 lies over as much as 360° of the surface of the drum 4. However, other degrees of envelopment are known which can then be used together with a suitable number of rotatable transducers.

Fig. 2 schematically shows a device for a recording/playback system which combines the control track 20 and the movement of the rotatable transducer or main wheel 22 for scanning inclined tracks on a tape 24. During recording, the main wheel 22 is servo-controlled by a comparison circuit 26 which emits a drive signal on the basis of a reference signal 28 and a signal from a pickup 30 which rotates at the same speed as the main wheel and is driven by the main wheel's motor 31. During recording, the signal indicating the speed of the main wheel 22 is also recorded in the control track 20 by a stationary transducer 32. - j playing, the speed and thus the position of the main wheel 22 is controlled in relation to the band 24 which is in motion, in accordance with the signal which is played back from the control track 20.

When the band 2, which is under tension, is pulled around the surface of the drum 4, there will be friction between the band and the drum. The effect of the friction is that you get different

tension in the belt between the inlet point and the outlet point for the belt 2 on the surface of the drum 4. The tension in the belt 2 increases exponentially from the inlet point to. the tape's 2 exit point. Therefore, the size of the tape's stretch on the surface of the drum 4 will not be linear, but follow an exponential function. The tensile stress and stretching of band 2 is given by this equation:

In this formula is: Tm. n the tension in the band 2 at the guide part 14 which forms the band's entry point towards the surface of the drum 4, T the tension in the band at the guide 16 which is the band's 2 outlet point, y is the coefficient of friction that applies between the band 2 and the surface of the drum 4 as the band passes over, 0 is the wrapping angle of the belt 2 around the drum 4, R is the radius of the surface of the scanning drum, A is the cross-section of the belt 2 and E is the Young's modulus of the belt 2.

From the relationship reproduced here, it can be shown that there exists a point on the belt around the surface of the drum where the magnitude of the stretching of the band is equal to half of the total stretching between inlet and outlet points. This is the neutral point for stretch where the stretch from this point to the inlet point and the outlet point of the belt is the same. The formula for this point can be expressed at an angle 0, measured from the inlet point of the tape as follows:

From this equation it can be seen that this is correct regardless of the specific value for input and output voltages for a specific case. To show the significance of this, it can be assumed, as shown in fig. 1, that a transducer 18 which is stationary and must cooperate with the guide track is located at the neutral stretching point which will be at an angle Øp around the drum 4 from the belt's 2 inlet point. The transducer 18 produces a longitudinal information track 17 along the band 2. Although the value Øb will be a function of the special value of y that applies here, the location of the neutral stretching point will, due to the exponential nature of the function, as shown in fig. 1, not be at the geometric center point or have a mean value between the inlet and outlet points of the tape 2. If one now assumes that some information is recorded in an inclined track on the tape 2 by the transducer 6 under predetermined tensile conditions in the tape 2 at the inlet and outlet points 14 and 16 and one looks at the belt 2 which is in contact with the drum 4, one will find that the recorded inclined tracks and the path of movement of the transducer will appear as superimposed straight lines as shown in fig. 3. If the same piece of tape is now played with the same known voltage conditions as during recording and the envelope signals are observed on an oscilloscope, the signal envelope will essentially be a regular rectangle as shown in fig. 4. Where the voltage is the same for both recording and playback as assumed in this example, the results indicated will be essentially independent of where the guide track transducer is placed around the drum. In practically used recording/playback systems, however, there is not the same tension or tensile stress on the tape during recording, recording and playback.

It must therefore now be assumed that the same piece of tape that has been recorded as explained above is played back with different strain conditions than those prevailing during recording. It can e.g. it is assumed that the stretch during playback is higher than the stretch during recording. If you look again at the tape under the new tension conditions, it will appear as shown in fig. 5. As shown in fig. 5, the tape is stretched under the higher playback stresses with deviation or wrong tracking between the recorded track, which has an exponential shape, and the linear path of the inclined track transducer. With the device shown in fig. 1 and the control track 17 as shown, during playback the position of the rotary transducer 6 can be controlled by a control servo action so that the maximum amount of information communicated to the rotary transducer takes place at the point where the head of the control track transducer is located. This may be so because the position of the control track head is at the point around which the track control for the rotary transducers is servo operated.

If an oscilloscope is used to observe the envelope curve for the played signal with the higher voltage in the band during playback, the envelope curve will appear as shown in fig. 6, with a loss of information due to wrong tracking caused by the extra stretching of the tape.

If one now assumes that the transducer head for the system in fig. 1 is the stationary transducer 19 instead of the transducer 18, the transducer 19 can be placed in the middle of or in the middle between the inlet point 14 and the outlet point 16 of the belt 2. The guide track transducer 19 is thus located equidistant from the inlet and outlet points for the belt around the drum 4. If the tape is now recorded under one stretch ratio and played back under a higher stretch ratio with the control track 19 used, the envelope curve for the played signal on an oscilloscope will appear as shown in fig. 7. Figures 6 and 7 show that in fig. 7 where the guide rail head 19 is used,

the wrong track following will be greater at one end of the track than at the other, in contrast to the symmetry in fig. 6. This is indicated by the dimensions a, b and c; c>> a and c> b >a.

It will thus be seen that there is a point around the circumference of the drum where the guide track transducer head can be placed to reduce the effect of wrong track following due to voltage variations and thus also stretching of the belt around the drum. As the stretching from the neutral point is evenly distributed from inlet point and outlet point, it has proven particularly advantageous to place the guide track transducer, e.g. the head 18 in fig. 1, in the neutral stretching point.

Although the invention is explained here by reference

to a simple rotary transducer with an essentially 360° wrap around the drum, as shown, the same principles can be used for recording/playback systems where other wrapping angles for the tape, different numbers of sound heads and different coefficients of friction are used.

With a tape having a Young's modulus "E" in the range of 0.3115 to 0.3577.IO<5> kg/cm<2>, will-e.g. the band's cross-section "A" should be approximately 6.45 . 10 — 3 cm, while the drum's radius "R" can be 5.2385 cm. The values reproduced below are based on the above conditions and also apply to an envelope angle 9 of 360° and 180° with an input pull T. of 0.2268 kg for friction coefficients p which can lie in the range from 0.2 to 0.3.

x) Wrapping tape for the tape around the drum,

xx) Angular position of the guide track head measured in relation to the belt's direction of movement for the belt's entry point on the drum.

It should also be noted that although the stationary guide track transducer is located around the guide drum as explained, the guide transducer can be arranged to interact with the belt at this point in a number of different ways. For example, the steering transducer can be mounted in or through the surface of the steering drum as shown. The control transducer in a magnetic recording/playback system can e.g. be a standard horseshoe-shaped magnet head. The control transducer 40 can, as shown in fig. 8, is placed at the desired point around the control surface 42 on the side 44 of the tape 46 that faces away from the control surface 42. With this device, the tape 46 can be arranged for recording the control tracks on the side 44 or recording of the control track takes place on the side facing the control surface 42 through the band 46. In fig. 9 further shows that a part 50 of the control track transducer can be placed in the control surface 52 with a cooperating further part 54 of the control transducer placed on the outside of the recording medium 56. With this design, the control signal can be arranged in or on both sides of the medium 56.

Claims (4)

1. Device for controlling tape in tape players, where the tape is transported by friction over a cylindrical tape guide surface in cooperation with a rotating signal transducer along paths extending transversely to the direction of movement of the tape, where the tape transport device sets up a predetermined tension in the tape at its inlet port on the belt guide surface, and with a significantly greater value for the stretch at the outlet point of the belt on the said surface determined by the extent of the belt path on the guide surface and the friction ratio between the belt and the surface, thereby producing a specific stretching of the belt on the said surface, and where a stationary signal transducer for transforming control information along the length of the belt is arranged to control the stretching of the belt, which stationary transducer is arranged to cooperate with the belt at an intermediate point between the inlet and outlet points on the surface, characterized in that the position of the intermediate point is such that the stretching so m appears in the part of the belt that lies between the inlet point (14) and the said intermediate point essentially corresponds to the size of the stretching of the part of the belt that lies between the said outlet point (16) and the intermediate point, the angular position 0 tr for the stationary signal transducer (control track head 18) for control information measured from the aforementioned inlet point, is' determined by the equation: where 0 is the wrapping angle of the belt around the belt guide surface and y is the coefficient of friction between the belt and the surface. 2. Device as stated in claim 1, characterized in that the stationary control signal transducer (control track head 18) is arranged in the band control surface (4). 3. Device as stated in claim 1 or 2, characterized in that the stationary control signal transducer (control track head 40) is on the side (44) of the belt (46) which faces from the belt guide surface (42). 4. Device as specified in claim 1 or 2, characterized in that the stationary control signal transducer has two parts, one (50) of which is positioned so that it interacts with the side of the tape that lies on the tape side surface (52), while the other (54 ) of the aforementioned parts cooperate with the side of the belt facing away from the belt guide surface.