DE2658677A1 - INFORMATION CARRIERS, METHODS FOR ITS PRODUCTION AND METHODS AND DEVICES FOR RECORDING AND / OR REPRODUCING INFORMATION WITH THE HELP OF THE INFORMATION CARRIERS - Google Patents

Description

Information carrier , method for its production and methods and devices for recording and / or reproducing information with the aid of the information carrier

The invention relates to a disk-shaped recording medium, a method for producing the recording medium as well as methods and devices for recording information on the recording medium and for reproducing the recorded information

In use, the recording or recording device according to the invention is Information carrier rotated, and by the invention an accurate recording and reproduction of the information on or guaranteed by the recording medium even if the recording medium has a performs an eccentric rotary movement.

Rotatable information carriers have been used for recording and reproducing information for many years. as Examples of such information carriers are the known records, in which the information is in the form mechanical corrugations are recorded, which with the help of an appropriate device, e.g. a pickup needle, can be sampled and converted into audible tones. To be on a

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First of all, recording record information becomes a Father record produced, by means of which numerous records of the same type are then pressed. During the production of the father plate, the acoustic tones are converted into corresponding electrical signals, by means of which a corresponding transducer, e.g. a sound recording needle, actuated is to provide the father plate with the appropriate corrugations, which are generally along a spiral track extend around the axis of rotation of the father plate. As a further example of a disk-shaped information carrier, let called a magnetic plate, which makes it possible to place video information, acoustic information or on its surface to record or store digital data. In the case of a magnetic disk, the signal information can either be in the form of a continuous spiral track or on concentric circular tracks can be recorded «Another example of a disc-shaped information carrier is the so-called image disk. In one embodiment of such an optical disc, video signals and acoustic signals are used in the form of an irregular area modulation, e.g. recorded in the form of depressions or grooves that can be scanned optically. At a With other types of image plates, surface modulation is detected with the aid of an appropriate needle.

If a disk-shaped information carrier of the type described above is used, this is usually opposite rotated by a drive means such as a turntable, a rotatable shaft or the like of the transducer. Here, the information carrier occasionally experiences a lateral displacement in a generally radial direction, so that it performs an eccentric rotary movement. Such a lateral displacement can be attributed to inaccuracies in the drive device for generating the rotary movement. For example, if the information carrier has a central opening, the center of which is on the axis of rotation, a

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certain clearance between the opening and the drive shaft or an associated guide rod to such lateral displacement and therefore lead to an eccentric rotary movement.

If the information is recorded on the disc-shaped information carrier in the form of concentric circular tracks, the transducer that scans the information carrier must in order to record or reproduce signals, ideally be guided along a precise circular path · However, every eccentric rotation of the disk causes corresponding deviations in the track being scanned. Is the plate with a spiral information track of predetermined pitch or division, the transducer must use the information carrier for recording or reproducing the information be passed over, ideally guided exactly in accordance with the course of the spiral track. Also in this case leads every eccentric rotation of the disk leads to an uneven displacement of the information track Trace not readily noticeable, i.e. an eccentric rotation of the disk during manufacture of the master disk or when playing a copy is difficult to detect. The reason for this is that the width of the information track and the distances between parallel spaces of the track are relatively large compared to the amount of eccentric rotation. If, on the other hand, there are traces of information or their parts close together, as is necessary with magnetic or optical disks, can be an eccentric rotation easily recognized by a corresponding distortion during recording or playback. For example, if the information track has a width in the range of about 1 to 3 micrometers and the track spacings are about 2 to 3 micrometers, the lateral displacements of the plate or the eccentric rotation must not exceed 0.1 to 0.5 micrometers

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An eccentric rotation "due to deviations in the drive mechanism for the plate" leaves avoid each other in many cases. This also applies to deviations in the drive device for the converter that are too Deviations in the pitch of the track give rise to. However, can. Pitch inaccuracies or division of the information track due to deviations of the drive shaft for the disk, up to now unfortunately only avoided by using extremely expensive machining processes in the manufacture of the drive device.

The invention is based on the object of creating an improved disc-shaped information carrier which allows the occurrence of an uneven pitch or to compensate for the division of the information track during the recording or reproduction of signals in which a distortion of the signals during recording or reproduction is avoided even with an eccentric rotation of the disk, and in which there is a predetermined circular track which is used as a reference track to determine the correct one Establish information track during recording or playback of signals even if the disk is a result a lateral displacement performs an eccentric rotation. Furthermore, a method for producing such a disk-shaped information carrier according to the invention is intended Finally, methods and devices are to be created that enable precise recording or recording. To enable reproduction of information using a disc-shaped information carrier even if the Information carrier executes an eccentric rotation as a result of a lateral displacement.

To solve this problem, a disk-shaped rotatable information carrier has been created by the invention, which has a first section which is suitable for recording information signals, as well as one of them

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separated circular track containing reference information which enables a transducer to record or Reproduction of signals to lead exactly along the correct path.

The invention also provides a method for recording information on a disk-shaped sheet according to the invention Information carrier has been created, which includes hate, to record information signals while the information carrier is rotates so that an information track is created, to scan a predetermined cough along the circular track and thereby any eccentric rotation of the Information carrier to be detected, and the generation of the recording track as a function of the detected to influence eccentric rotation so that the eccentric rotation is compensated. Within the scope of the invention can a master disk can be produced in each case after the information carrier produced in this way.

Finally, the invention provides methods and devices for recording and / or reproducing information has been created by means of a plate-shaped information carrier of the type described above, which make it possible to record and reproduce the information in such a way that there is essentially no distortion, when the information carrier shifts sideways or performs an eccentric rotation.

In the following the invention is explained in more detail with reference to schematic drawings of exemplary embodiments. It shows:

Fig. 1 is a plan view of an embodiment of an information carrier according to the invention;

FIG. 2 shows a signal recording device for use in connection with bits of the information carrier according to FIG. 1; FIG.

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3A to 3B each show a partial section to illustrate the mode of operation of a part of the device according to Fig. 2;

FIG. 4 is a graphic representation to illustrate the control method used in the device according to FIG ;

Fig. 5 shows a signal reproducing apparatus for use in connection with the information carrier according to FIG. 1; and

6 shows a further embodiment of a reference track with which the information carrier according to FIG. 1 is provided and which can be used in conjunction with the devices according to FIGS.

In Fig. 1, an embodiment of a disk-shaped information carrier 1 according to the invention is shown. The plate 1 is provided with a circular opening 2 for receiving a drive shaft or guide rod, around its axis the plate is rotated. The top and / or the underside of the plate is provided with a section 3, which for Recording of information signals is used, and also one with the axis of rotation of the disk is concentric circular Lane 4 is present, which contains reference information described below. Enclosed in the embodiment according to FIG the circular track the section 3 for recording information. In another embodiment, the circular track is enclosed by the section 3 receiving the information. If the record 1 resembles a record, the information recording section 3 is provided with a substantially spiral-shaped information track which Has surface corrugations, which with the help of a needle or the like. sampled and converted into corresponding electrical signals which in turn are converted into acoustic signals during playback

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Disk 1 around a magnetic disk becomes the information recording section 3 is provided with a substantially spiral-shaped information track on which information signals are magnetically recorded in a known manner, or with several concentric circular magnetic tracks · In another Embodiment, i.e., when the disk 1 is an optical disk, the information recording section contains 3, a spiral track with pits or grooves representing the video signals. As mentioned at the beginning, these Vertte fungen or grooves either visually or with the help of a needle or the like. sampled to recover the information signals.

The circular track 4 is separated from the information recording section 3, and the associated reference information are formed by a predetermined detectable pattern consisting of certain markings, e.g. a light reflective pattern, a magnetically recorded reference signal, an optically detectable pattern or the like.

As will be explained below, the or each information track of the information recording section 3 has such a relationship to the circular track 4 that the distance between any point within the information recording section and the circular track is set in accordance with a predetermined relationship regardless of any concern to an eccentric rotation or a lateral displacement of the disk 1 during the recording of the signals. To the For an explanation of the invention, it is assumed that the circular track 4 contains a light-reflecting pattern. "Of course The reference information forming this circular track could also be formed by a predetermined magnetic signal will. It is also assumed that the information recording section 3 is given a spiral track with information signals, and that the signals are in the form of irregular ones Surface modulations, e.g. depressions or grooves,

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are drawn. Bel the plate 1 can thus be a Record or an optical disc act · Alternatively, the information recording portion 3 of the disc with magnetic recorded information signals in the form of a spiral Be provided on the track.

2 shows a device for recording information signals on the information recording section 3 of the disk according to FIG. ₀ 1. In the present case, the disk 1 is to be used as a father disk by means of which numerous copies are to be pressed. The plate 1 includes a base 5 'on which a metal film 6 made of aluminum or another light-reflecting material has been applied, for example by vapor deposition. The film 6 according to FIG. 2 corresponds to the circular track 4 according to FIG. 1. This track has a width of about 1 mm and consists of a film with a thickness of about 0.1 micrometers. According to Fig. 3A, the film 6 is provided on its upper side with a slot or a groove 7 which has a V-shaped cross-section or some other suitable cross-sectional shape, so that a circular interruption is present on the upper side of the film. The groove 7 has a width of about 4 micrometers. If light is allowed to fall on the top of the film 6, the light is thus reflected along a predetermined path, but with the exception of that part of the light which hits the groove 7. This is discussed in more detail below.

The top of the pad 5 is convertible with a Layer 10 provided of uniform thickness «, the described Disk 1 is placed on a turntable 9 with a rotatable shaft 8 · The shaft δ is in the central opening 2 of the plate insertable. The in Fig. 2 by the Diagram block B contains part of the device indicated a recording device by means of which the convertible layer 10 is influenced by a support which is with the information signals is modulated while the disk

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circulating · ¥ ie explained below, can be the convertible Layer 10 consist of a light-sensitive covering compound which modulates the action of a with the information signals Light beam is exposed, so that a latent image of the information to be recorded is generated on the layer.

In the device according to FIG. 2, the receiving device B includes a transducer 22 for sweeping over the top of the Disk 1 along a predetermined spiral path or track. The converter 22 is driven by a drive device (not shown) relative to the plate 1 moved radially inwardly, while the plate about the axis of the rotating shaft 8 is rotated. While this movement of the transducer 22 is related to the rotational movement of the disk, it does lead Inaccuracies in the rotatable shaft 8 result in an eccentric rotation of the plate, so that a lateral displacement occurs between a given point on the top of the plate and the transducer. This could lead to the creation of an information trail lead that deviates from the predetermined spiral track. According to the further description below is used in the creation of the spiral track by the wall-1-er 22 a compensation is brought about when an eccentric rotation of the disk 1 occurs.

Within diagram block A in FIG. 2 are facilities for sensing the lateral displacement of the disc 1 as it rotates. This includes a light source 11, optical elements 12, 15 and 16 for focusing the light of the light source 11 on the metal film forming the circular track 6 and further optical elements 14, 15 and 17 for detecting the light reflected by the metal film and for sensing lateral displacement of the plate 1 as a function of a feature of the reflected light. In the Light source 11 is preferably a helium-neon laser that generates a linearly polarized laser beam. This beam is passed through a beam splitter 12 * see above

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that part of the emitted beam reaches a light detector 13 from the beam splitter, while the other Part of the emitted laser beam is reflected and via a polarized beam splitter 14, a quarter-wave plate 15 and a condenser lens 16 is guided onto the plate 1. The polarized beam splitter 14 is the Direction of the linear polarization of the reflected by the beam splitter 12 laser beam b1 adapted so that im substantially the entire beam b1 reaches the quarter-wave plate 15 via the beam splitter, which latter is of a known type and serves to correspond to the linearly polarized coming from the beam splitter 14 Beam to emit a circularly polarized beam. The condenser lens 16 focuses the beam b1 on the metal film 6 in the vicinity of the groove 7 of Fig. 3A. The lens 16 creates a focused light spot with a diameter of about 4 microns.

As discussed in more detail below, at least a portion of the focused beam is off the surface of the metal film reflected off through lens 16 and quarter wave plate 15. This reflected light beam is circularly polarized, and therefore the quarter wave plate 15 'causes the beam to polarize linearly in one direction which runs at right angles to the linear polarization of the beam b1 which previously passed the plate 15 Has. The reflected beam polarized in this way, which now strikes the beam splitter 14, is passed through this beam splitter prevented from propagating in a straight line, and it is reflected towards the light detector 17. if if you choose the polarization directions of the incident and the reflected light beam accordingly, you can use the the same optical elements 14, 15 and 16 to use the Beam b1 to fall on the metal film 6 and the beam reflected by the metal film on the light detector 17 to direct. Thus the ways for the supplied and that fall

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reflected light in the arrangement according to FIG. 2 between the beam splitter 14 and the metal film 6 together * Bei another embodiment stand for the incident and the reflected light have separate paths.

The light detector 17 generates a control signal with a certain Feature proportional to the intensity of the light beam supplied to it from the metal film 6 will. In the preferred embodiment, the size of this control signal is proportional to the intensity of the Light detector 17 falling light. As in Flg. 3B to 3D represented, represents the strength of the control signal generated by the light detector 17 size and direction of the lateral displacement of the disk 1 that occurs during the rotation of the disk. Assume that the beam b1 strikes the metal film 6 in the vicinity of the groove 7 so that that part b1 · of the beam passes through the top of the metal film is reflected while a second part b1 "hits the groove 7 and therefore not in the direction of incidence is reflected. When the disk 1 rotates properly, the metal film 6 becomes a predetermined one as shown in FIG. 3B Part b1 'of beam b1 is reflected. In other words, the groove 7 confronts the disk 1 as it rotates a fixed reference point, e.g., a reference point established by optical elements 12, 14, 15 and 16 predetermined position. When the plate shifts in a lateral direction, for example radially as shown in Fig. 2 inside, the groove 7 is displaced relative to the fixed reference point in the manner shown in FIG. 3C, so that a larger part B1 'of the incident beam b1 through the Metal film 6 is reflected. Therefore, the reflected beam falling on the light detector 17 has a higher intensity, so that a stronger control signal is generated. If, on the other hand, the plate is displaced radially outward as shown in FIG. 2, so that the groove 7 is offset from the fixed reference point in the manner shown in FIG. 3D, becomes practical

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no part of the incident light beam b1 is reflected by the metal film 6. In this case the intensity is the same of the reflected light beam impinging on the light detector 17 is a minimum, so that the corresponding control signal assumes its smallest value.

The changes in the intensity of the control signal that the light detector 17 as a function of the detected displacement of the groove 7 generated relative to the fixed reference point when the disk 1 rotates eccentrically are graphically shown in FIG shown »If the distance between the center line of the groove 7 and the fixed reference point corresponds to the distance S, as is the case with an error-free rotation of the disk according to FIG. 3B is the case, the strength of the control signal generated by the light detector 17 is represented by the T level. Relocated the center line of the groove 7 so that it coincides with the fixed reference point is shown in Fig. 3D substantially no part of the incident beam b1 is reflected back by the metal film 6 so that the control signal is its assumes the smallest value. During the normal rotation of the disk 1, of course, a portion b1 'of the incident beam must b1 are reflected so that the direction of displacement of the disk utilizing a decrease or an increase the intensity of the reflected beam can be determined can.

To changes in the control signal generated by the light detector 17 to avoid as a result of variations in the intensity of the light beam derIaserlichtquelle 11, the control signal relative to the intensity of the emitted laser beam "normalized" _o This is done essentially by means of a ünterteilungsschaltung 18 obtained by the light detector 17 generated control signal and which divides the value of the control signal by the value of the detected output signal generated by the light detector. In this way there are deviations in the control signal

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of the light detector 17, which are due to fluctuations in the intensity of the laser beam from the source 11, have no effect made because the corresponding deviations also appear in the detected output signal of the light detector 13. This “normalized” output signal generated by the dividing circuit 18 is amplified by a preamplifier 19 and fed to the recording device in accordance with diagram block B in Fig. 2 to set the track longitudinally which the transducer 22 is guided, so that lateral displacements of the plate 1 are compensated, which are their cause in an eccentric rotation of the plate.

Within the device B, the information signals are fed to an input terminal 24a in order to modulate a carrier, so that the recording device 22 modulates the carrier on the disk 1 that is modulated in accordance with the information records. Indicates the recording facility or the Transducer 22 on a needle, the needle leads under the influence of the carrier modulated in accordance with the information Information signals corresponding mechanical vibrations. Here the needle cuts a corresponding groove the top of the plate as the plate rotates and the needle, for example, along a substantially spiral shape Track is guided. If a magnetic disk is to be used, the carrier is activated by a corresponding preload signal which is modulated with the information signals, and the transducer 22 is in a known manner as a magnetic recording head educated. In the embodiment of Fig. 2, the transducer 22 is an optical recording head formed, in which a light beam is used as a carrier, which is supplied with the aid of an input terminal 24a Information signals is modulated. The light beam modulated by these signals is directed onto a layer 10 a photosensitive masking means to produce a latent image of the information signals which is then applied to

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ORIGINAL SNSPEGTED

known way is developed and fixed.

According to Fig. 2 there is e.g. an argon laser 23 as the light source, which generates a laser beam which is fed to a light modulator 24 of known type, which is used as a carrier The laser beam used is modulated with the aid of the information signals supplied via the input terminal 24a. The one modulated in this way Laser beam b2 is reflected back through a reflective surface such as a mirror 21 and through a condenser lens 25 focused to on top of the layer 10 of the covering means on the plate 1 according to the information to generate modulated light spot. Here, the modulated laser beam is along a substantially spiral Track guided while the transducer moves generally radially inward and the disk 1 is rotated about its axis. When the plate shifts radially during its rotation, so that it performs an eccentric rotational movement, gives way the actual information track along which the transducers are 22 is moved relative to the top of the plate, in the manner explained above, from the ideal spiral-shaped Track off. When the information recorded on the disk is reproduced, or when the disk is manufactured If numerous copies are used that are to be played back, these deviations affect the recorded information track the reproduced signals, especially if the disc is not exactly in the same Rotated eccentrically while the signals are being played back.

This difficulty is substantially eliminated by the fact that during the generation of the information signals containing Recording track the position of the point at which the modulated laser beam b2 hits the cover layer 10 of the Plate 1 hits, depending on the extent of the felt eccentric rotational movement of the plate is changed. For this purpose, the amplified taken from the preamplifier 19 is used

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Control signal via an additional amplifier 20 of a position determining device for the mirror 21 supplied. For example, the mirror 21 can be connected to a rotating coil, so that the path along which the modulated laser beam b2 is propagated is amplified by that fed to the moving coil Control signal is determined. Thus, the circular track 4, to which the metal film 6 with the groove 7 belongs, forms together with the sensing device, which is composed of the light detector 17 and the adjustable mirror 21, a servo device, the laser beam 2b modulated with the information then also opposite the surface of the plate 1 holds in the correct position when the plate is displaced radially or rotates eccentrically.

The servo control action of the arrangement just described can be understood if, for simplicity, it is assumed that the laser beam b2 modulated with the information can only sweep over a circular information track. Will the Plate 1 displaced radially outward by an amount Δγ, the intensity of the in the direction of the light detector 17 reflected light in the apparent from Fig. 3D Way reduced. This displacement Δγ of the plate would increase a corresponding shift Δγ of the circular track lead, which is swept over by the modulated with the information beam b2. However, proof of the change leads of the light intensity by the light detector 17 to the fact that a control signal, for example of the rotating coil supporting the mirror 21 is supplied so that the reflection path along which the modulated beam b2 is emitted changes, and that the light spot on the surface of the plate 1 is also displaced by the amount Ar. Although the plate can rotate eccentrically, therefore, the information track swept over on the surface of the disk becomes substantially kept at the correct distance from the circular track 4, in accordance with a predetermined relationship. Though it was assumed above that this

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True reference length is a fixed route, i.e. the information track is circular, but should now be apparent be that the instantaneous value of the distance between the point of incidence of the modulated beam b2 and the circular Track 4 can vary according to a predetermined function, so that on the surface of the disk a spiral information track is painted over.

A similar control process is performed at the point of incidence of the modulated beam b2 to change on the surface of the plate when the plate according to FIG. 3C by a Amount Ar is shifted inward. In terms of A more detailed explanation of this control process should be superfluous in the above description.

After the information signals supplied via the input terminal 24a recorded in the form of a latent image on the surface of the resist layer 10 in the manner described are, you can remove the plate from the turntable 9 and develop and fix it in a known manner. This creates surface irregularities on the plate in the form of depressions or grooves that the previously exposed Parts of the covering medium layer 10 correspond. After developing and fixing, the surface becomes the resist layer plated with nickel, chrome or another material «After plating, the plate can be used as a father plate for pressing numerous copies can be used · Alternatively, the nickel or chrome plated plate can be used in a known manner use to press a father plate, which in turn is used to make numerous copies. By both Manufacturing process appear the surface irregularities of the plate 1, which modulated on the exposure of the covering medium layer 10 with the corresponding information Light are due, accordingly in the copies, so that they can be detected with the help of an appropriate converter to play back the recorded information.

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Although a recording process has been described above, in which the plate 1 with a surface layer made of a photosensitive Cover material is provided, which is exposed to the action of light, which according to the information is modulated, but it should be noted that the plate can also be covered with a layer of another variable material and could modulate a corresponding carrier in order to deform this material so that the information representative irregular surface corrugations arise. For example, the changeable material can be act as a thermoplastic material, and thermal energy could be used as a carrier, which corresponds to the one to be recorded Information is modulated. Alternatively, one could use an electrostatic or a changeable material Use electrophotostatic sensitive material, and the carrier could be formed by an electrical charge corresponding to the information signals to be recorded is modulated; after all, one could work with a light beam modulated according to the information, which makes it possible, if necessary, to remove an electrical charge that was on the surface of the material

Fig. 5 shows a preferred embodiment of a playback device, which is suitable for reproducing the information signals which are described with the aid of the information signals described with reference to FIG Device within section 3 of disk 1 have been recorded. The plate 1 thus has surface irregularities in the form of corrugations or depressions or grooves within the section 3 and is circular with a Provided track to which the described groove 7 belongs. For use, the disk is placed on the turntable 27, and a rotatable shaft 26 is inserted into the central opening of the plate to rotate the plate. Any radial Displacement of the plate, which occurs e.g. with an eccentric rotation, is represented by the diagram block A indicated facility demonstrated that essentially

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", OPiCTED

is of the same type as that described with reference to FIG. 2, so that a new description should be superfluous. It should only be noted that any radial displacement of the Plate is felt in that a corresponding movement of the groove 7 is detected, whereby in the described Way, the intensity of the light beam is influenced, which according to Fig. 3B to 3D from the circular track to the light detector 17 is reflected. Thus, the preamplifier 19 generates an amplified control signal, the size of which is felt radial displacement of the plate 1 is proportional.

Of course, the device for reproducing the information signals be compatible with the receiving device described with reference to FIG. According to Fig. 5, the playback device is scanning the information signals present on the plate as surface irregularities, namely with With the help of a light beam, e.g. a laser beam, falling on the surface of the plate, the modulation of the light reflected by the plate is detected. For this purpose a light source, for example a helium-neon laser 28, is provided which has a linearly polarized laser beam is directed at a beam splitter 29, the latter essentially corresponding to the beam splitter 14 according to FIG and serves to transmit light that is linearly polarized in a predetermined direction, but substantially reflect all light that is linearly polarized at right angles to the transmitted light.

The laser beam emitted by the laser 28 passes through the beam splitter 29 and a quarter-wave plate 30, which corresponds essentially to the quarter wave plate 15 of FIG. 2 and serves in a known manner to the to convert linearly polarized laser beam into a circularly polarized beam, which is deflected by a mirror 21 so that it arrives at a condenser lens 31 as a beam b3 to form a light spot on the surface of the plate

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to be focused. The light beam b3 hitting the surface irregularities of the plate is reflected in such a way that that he again runs the condenser lens 31 to move in the opposite direction to the mirror 21 to arrive. The reflected light is corresponding to that recorded on the disk Information signals are modulated and passed through the mirror 21 to the quarter wave plate 30. the Circular polarization of the modulated beam is transformed into linear polarization by the quarter wave plate transformed, with the polarization direction now essentially at right angles to the linear polarization direction of the laser beam emitted by the laser 28 runs. Therefore, the modulated light beam becomes substantially complete reflected back by the beam splitter 29 and passed to a light detector 32, by means of which the information to be recovered.

In the embodiment according to FIG. 5, in which the mirror 21 and the condenser lens 31 forming a transducer 33 which can scan a spiral track on the top of the information section 3 of the disc is not shown Drive means are provided which serves to advance the transducer radially while the disk rotates. If the transducer 33 is to scan concentric circular tracks on the disk, a corresponding drive device is required used to move the transducer radially.

If the groove 7 of the circular track at an eccentric Rotation of the plate displaced radially, e.g. as a result of a corresponding movement of the rotatable shaft 26, is used in FIG the same way as in the recording device according to FIG. 2, the amplified by the preamplifier 19 and by the Additional amplifier 20 further amplified the control signal to adjust the mirror 21 so that the point of incidence of the beam b3 is correspondingly displaced on the surface of the plate in order to compensate for the radial displacement. The mirror 21 can

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e.g. be connected to a moving coil, so that its Angular position is changed depending on the size of the control signal * Thus, the beam b3 hits the Surface of the plate at a point opposite the groove 7 of the circular track 4 corresponding to a predetermined Relationship is established relatively precisely. In an embodiment in which the information signals are longitudinally Of course, this "predetermined relationship" becomes a spiral track recorded on a spiral track Scanning path set for beam b3.

The control of the point at which the beam b3 hits the surface of the disk while the recorded Signals are reproduced corresponds essentially to the control of the beam b2 during the operation of the recording device 2, so that a renewed description with respect to the reproduction device according to FIG. 5 is unnecessary should.

Of course, the playback device of Figure 5 must be compatible with the disk used. Is it e.g. around a record, one must use a corresponding stylus as transducer 33. Is the plate 1 a Magnetic disk, the transducer 33 must be designed as a magnetic playback head of a known type.

In the embodiments described, it was assumed that the reference information within the circular Track 4 is formed by the groove 7 of the light reflective metal film 6. In another embodiment For example, this reference information can simply be formed by a narrow, light-reflecting track that is one width of about 4 microns. Figure 6 shows another embodiment a circular track 4 with a first circular pattern 5A of evenly spaced circumferential, Light reflecting elements with a first

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Periodicity, as well as with a second circular pattern 5B adjacent to it of light-reflecting elements distributed at uniform circumferential intervals with a second periodicity. A light spot 34, which corresponds to the focused light beam b1, is superimposed on these adjacent circular patterns. According to FIG. 6, a part of the luminous spot 34 covers the pattern 5A and another part covers the pattern 5B. The intensity of the light reflected to the light detector 17 thus contains a first component corresponding to the periodicity of the reflective elements 5A and a second component corresponding to the periodicity of the elements 5B. According to FIG. 6, the first component of the light intensity has a higher frequency than the second component. If the disk 1 rotates without errors, so that the circular track 4 assumes the correct position in relation to the fixed reference point determined by the light spot 34, the first higher-frequency component of the reflected light has a predetermined first intensity, while the lower-frequency component of the reflected light is characterized by a predetermined second intensity. Any displacement of the circular track 4 with respect to the stationary light spot 34, for example _β as a result of an eccentric rotation of the plate, leads to a corresponding change in the intensity of the components of the light reflected to the detector 17, which differ in terms of their frequency. This change in the intensity values is used to generate a control signal which corresponds to both the direction and the magnitude of the radial displacement of the plate. As before, this control signal is used to adjust the track swept by the transducer 22 or the transducer 33 so that any eccentric rotation of the disk is compensated for.

The exemplary embodiments described can be modified in the most varied of ways within the scope of the invention. It is e.g. possible as a verifiable sample within the

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circular track 4 represents the reference information, a predetermined magnetically recorded signal, optically detectable markings or the like «to use. The recording converter 22 and the reproduction converter 33 can be modified in accordance with the information given above will. For example, the transducers can each have an electron beam for recording or reproducing information produce.

Expectations %

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Claims (1)

EXPECTATIONS ■ Rotatable information carrier on which information signals are located -. record, and / or by means of "whose In-" display the formation signal ©? with © Inem a first and a disk-like body having a second surface, i c h η e t known by the fact that on a first section (3) at least the first information area & ignale can be recorded »and that at least on the named side a separate circular track (4; 5A, 5B; 6) is present, which differs from a first section and contains reference information (5A, 5Bj 7). 2, information carrier according to claim 1, characterized in that that the circular track encloses the first section, ».-". 3 «information carrier according to claim 1, characterized ₉ that the" circular track is enclosed by the first section, 4 .. information carrier - Naeh claim 1, characterized in that 3 to the first section a © spiral track belongs, along which information signals are records "are respectively" 5. Information carrier aach claim 4 _S characterized ρ that the longitudinal d © r.-circular track existing train information can be detected in order to determine any existing eccentric rotation of the information carrier * 6. Information carrier according to claim 5 »characterized in that the reference information is a a predetermined pattern of a detectable feature is " 7. Information carrier according to claim 6, characterized in that that the predetermined pattern reflects light. 709828 / 06SS ORIGINAL INSPECTED 8, information carrier according to claim 5, characterized in that the distance between any point is also set along the spiral track and the circular track in accordance with a predetermined relationship is when the information carrier makes an eccentric rotation during recording of the information signals Has. 9. A method for recording information signals on a rotatable information carrier having a circular track, in which the circular track is provided with a detectable predetermined pattern, with measures to rotating the information carrier about an axis and recording the information signals on the information carrier while this is rotated to produce an information track, characterized in that the predetermined Pattern (5A, 5B; 7) along the circular track (4; 6) detected during the rotation of the information carrier (1) is to determine any eccentric rotation of the information carrier, and that the generation of Recording track depending on the felt eccentric Rotation of the information carrier is controlled so that the eccentric rotation is compensated. 10. The method according to claim 9, characterized in that for detecting the predetermined pattern for sensing a eccentric rotation of the information carrier, a control signal is generated which has a feature which as a function varies from the size and direction of the eccentric rotation of the information carrier. 11, method according to claim 10, characterized in, that for controlling the generation of the recording track to compensate for the eccentric rotation, the recording track of the information carrier is displaced relative to a predetermined path as a function of the control signal. 70982Ö / 06BB 12. The method according to claim 10, wherein the predetermined pattern reflects light, characterized in that for Generating the control signal a light beam is directed to the light reflecting pattern that the light beam from the pattern is reflected in the direction of a light detector, and that a control signal is generated, the size of the Intensity of the light beam impinging on the light detector is proportional. 13. A method for producing a disc-shaped information carrier, which has a predetermined detectable pattern in the form of a circular track on a surface, and which includes a layer of a convertible material which essentially completely covers this area Measures to rotate the disc or plate about an axis, to modulate a carrier with information signals and to exposing the convertible layer to the action of the modulated carrier while the disk is being rotated so that a Information track is generated, characterized in that the predetermined pattern is detected while the disk rotates to feel any eccentric rotation of the disk that the creation of the recording track is controlled by the location of the point at which the modulated carrier impinges on the convertible layer in Depending on the sensed eccentric rotation of the plate is changed in order to compensate for the eccentric rotation, and in that the convertible layer so treated is developed and fixed on the surface of the plate to to generate an irregular surface corresponding to the information signals. 14. The method according to claim 13 »characterized in that the predetermined pattern is a light reflecting pattern is and is thereby detected that a light beam from a stationary light source opposite the pattern on a predetermined Body is directed that the light beam from. the pattern is reflected off towards a light detector T0982S / 0S58 that one to the intensity of the reflected to the light detector Light beam proportional control signal is generated, and that the intensity of the light beam of a predetermined Level deviates when the light beam hits the pattern at a point that is due to an eccentric Rotation of the disk differs from said predetermined location. 15. The method according to claim 14, wherein the carrier is a second light beam and a convertible material light-sensitive masking compound is used, characterized in that the point at which the modulated carrier is on the convertible layer hits, thereby displacing it, that the modulated light beam in the direction of the layer of the photosensitive covering material along a predetermined Web is reflected, and that the reflection path of the modulated second light beam as a function of the control signal is changed. 16. Method of reproducing information on a disc-shaped information carrier have been recorded, to which a circular track with a predetermined a verifiable sample and a separate section of the information carrier with the information, with measures for rotating the information carrier about an axis and for scanning the separated section for the purpose the removal of the recorded information, thereby characterized in that the circular track is scanned to detect the predetermined pattern and thereby to feel an eccentric rotation of the information carrier, and that the scanning of the separated section is controlled as a function of the sensed eccentric rotation of the information carrier to the eccentric rotation to compensate. 17. The method according to claim 16, characterized in that 709828/08 5 5 that for scanning the circular track to detect an eccentric rotation of the plate, the circular track opposite a stationary device for scanning a pattern is rotated that a control signal is generated, the one Function of the sampled pattern and that the control signal is changed while the characteristics of the detected Pattern as a function of a displacement of the plate relative to the stationary device for scanning the pattern change. 1.8. The method of claim 17, wherein the separated portion of the plate is scanned along a predetermined path is characterized in that the scanning of the separated portion of the disk is controlled by the predetermined path is changed as a function of the deviation of the control signal from a predetermined value. 19. The method according to claim 18, wherein the predetermined pattern reflects light, characterized in that for Detecting the pattern a light beam is directed onto the pattern that at least a portion of the light beam passes through the pattern is reflected towards a fixed light detector, and that the control signal as a function of Size of that part of the light beam is generated which is reflected in the direction of the light detector. 20. The method of claim 19, wherein the discrete portion of the plate is along a predetermined helical shape Path is scanned, characterized in that the spiral shape of the path or track is changed when the Control signal deviates from the predetermined value, 21. Device for recording information on a disc-like information carrier and / or for reproducing recorded information, wherein the information carrier a circular track with a predetermined one 709 & 2Ö / O66B 26 ^ 6 7 7 .fr- having predetermined detectable pattern and an information signals receiving portion, with a drive device for rotating the information carrier about an axis and with a device for scanning the information signals on the information carrier along a predetermined path, characterized by an additional Means (14, 15 »16, 17) for scanning the circular track (4; 6) in order to detect the predetermined pattern (5A, 5B; 7) and thereby to feel an eccentric rotation of the information carrier (1), as well as by a control circuit (18, 19, 20, 22; 33), which responds to the perceived eccentric rotation of the information carrier in order to change the path, along which the first-mentioned scanning device scans the information signal section (3) so that the first Scanning device scans the information signal section along a path whose distance from the circular track is a corresponds to the predetermined relationship even if the Information carrier rotates eccentrically with respect to the first scanning device. 22. The apparatus according to claim 21, characterized in that a for the additional or second scanning device a fixedly arranged detector (14, 15 »16, 17), which detects the pattern present along the circular track, while the information carrier is rotated, and that a control signal generator (17, 18, 19, 20) is present, the is connected to the detector and generates a control signal whose value is always from a predetermined value deviates when the circular track relative to the detector as a result of an eccentric rotation of the information carrier is relocated. 23. The apparatus of claim 22, wherein the first scanning means is designed as a converter, characterized in that a device is available which makes it possible the converter (22; 33) and the information carrier (1) 709828/06 5 5 ORIOlNAL INSPECTED -as- 2 6 b 8 6 7 7 • V to be adjusted relative to one another with respect to the axis of rotation in the radial direction, and that to the control circuit for changing the path along which the first scanning device carries the information signal portion (3) scans, a device that is responsive to the control signal belongs to the transducer opposite to adjust the information carrier. 24. The device according to claim 22, characterized in that the pattern present along the circular track Light reflecting pattern (5A, 5B; 7) is that the detector has a light source (11) from which a light beam (b2) is directed to the light reflecting pattern, and that a light sensor (17) is arranged so that it receives light reflected by the pattern to produce an output signal proportional to the reflected light. 25. The apparatus of claim 24, wherein the light is reflective Pattern is a strip of light reflecting material, characterized in that to the light source includes means which normally allows part (b1 ·) of the light beam to fall on the strip, and that the Light sensing device generates an output signal proportional to the intensity of the reflected light (b1 '). 26. The device according to claim 25, characterized in that the control signal generator normally generates a control signal of a predetermined magnitude (T) when a predetermined part (b1 ^f ) of the light beam falls on the strip of light-reflecting material. 27. The device according to claim 26, characterized in that the control signal generator with the light source (11) optically coupled light detector (13), which detects a light signal that corresponds to the intensity of the light source emitted light is proportional, and that with the light detector and the light sensor (17) a device (18) 709828/06 ^ is coupled, which serves to the output signal with the normalize detected signal in order to generate the control signal, so that fluctuations in the control signal that arise on Fluctuations in the intensity of the light emitted by the light source are rendered ineffective. 28. The device according to claim 24, characterized in that the light-reflecting cough has a first circular one Pattern of periodically arranged, light-reflecting elements (5A) with a first periodicity and a this adjacent second circular pattern of periodically arranged, light-reflecting elements (5B) with a The second periodicity is that the light source includes a device which normally comprises a first part of the Light beam (34) on the first circular pattern and a second part of this light beam on the second circular Drops pattern, and that the light sensor (17) generates an output signal that corresponds to the intensity values of the first and the second periodic component of the reflected light is proportional, these components being proportional to the periodicities correspond to the light reflecting elements. 29. The device according to claim 23, characterized in that a light source (23) for emitting to the converter (22) of a light beam (b2) that optical elements (21, 25) are coupled to this light source to generate the light beam to conduct on the information carrier (1) that a modulator (24) for modulating the light beam with information signals there is that the adjusting device for moving the wander and the information carrier relative to one another on the information carrier determined a spiral information track, and that to the device for setting the Converter devices (20, 21) include which are used to adjust at least one optical element (21) to a bring about a corresponding shift of the point at which the light beam hits the information carrier. 709828 / Ö6BS 30. The device according to claim 23 »characterized in that a light source (28) for emitting to the converter (33) a light beam (b3) belongs to that optical elements (21, 29, 30, 31) are coupled to this light source directing the light beam onto the information carrier (1), where the light beam passes through the recorded on the information carrier Information is modulated that a detector (32) with the information carrier along a light reflection path is optically coupled to receive the modulated light beam reflected by the information carrier and to generate an information signal corresponding to the recorded information in that the adjusting device a spiral track for moving the transducer and the information carrier relative to one another on the information carrier ■ determined, and that the devices for adjusting the Converter devices (20, 21) include which are used to adjust the optical elements to a corresponding To bring about change in the position of the point at which the light beam hits the information carrier. The patent attorney: 7098 * 0/0668