DE102008056843A1 - Recording medium, method and apparatus for its production, and method for writing and reading information - Google Patents

Abstract

A recording medium (1) comprises a servo track or array of servo tracks suitable for guiding a scanning beam or a plurality of scanning beams of an information recording and / or reproducing apparatus and at least in sections for forming, displaying or storing main data. The servo track or the arrangement of servo tracks contains, at least in sections, a wobble signal (22) which contains period ranges (20) of a first signal with a period duration T0 and half period ranges (21) of a second signal. In this case half-period regions (21) of the second signal are inserted between the period regions (20) of the first signal.

Description

The The present invention relates to a recording medium, a method and an apparatus for its manufacture and a method as well a device for writing (i.e., for recording) and / or reading (ie for reproduction) of information on or from such such a recording medium.

Important Examples of such recording media include, among others, such as As magnetic recording media, so-called optical Recording media, for example so-called DVDs (eg DVD + R, DVD-R, DVD + RW or DVD-RW, etc.) where materials be used, their optical reflection or transmission properties for example, by a laser beam of suitable wavelength and / or Intensity reversibly or irreversibly changed can be. Such a recording medium becomes frequent also referred to as information carrier or data carrier. Unless it is "optical" recording media is the term "optical" in context the present presentation does not disclose the use of electromagnetic Fields or electromagnetic radiation with wavelengths Exclude outside the visible area. If, in this illustration, for the sake of simplicity, "one Servospur "is the speech, then it should - if Nothing to the contrary expressly or out of context results - also meant an arrangement of several servo tracks be.

State of the art

optical Recording media often have a preformed servo track that is a depression or an elevation opposite the surrounding area (the so-called "Landspur") can represent. Thus, for example, a preformed as a depression Servo track partially or completely filled with a material, its reflection or transmission property by laser light irradiation suitable intensity, reversible or irreversible, changeable is. In the preformed servo track can when writing information on the recording medium by means of an information recording device Data is written by the targeted change the reflection or transmission behavior of this device can be read out optically again. The areas, in which made such a targeted optical change are also called main data pits.

to Achieving the largest possible storage capacity the recording medium is the demand for as possible small dimensions of the main data pits and the intervening ones Areas (also called "land") become). To the accuracy requirements of the mechanical components the information recording device suitable for writing or reading and / or playback devices in an economically acceptable manner To keep frame, the servo track will read the stored in it Information usually also for the guidance of the scanning light beam of the information reproducing apparatus used used. In this way, the required leadership precision even with small dimensions of the data structure to be written achieved.

Often the servo track is provided with further features that an information about the linear recording speed can supply with which the data should be written. For example, the servo track may be sinusoidal about its Track center be deflected at a predetermined spatial frequency (which also referred to as "Spurwobble"). The spatial frequency For example, be true for a disc-shaped Recording medium the speed of the motor ("disk motor"), which sets this recording medium in rotation.

Some forms of such recording media are supplied - for orientation on an unrecorded data carrier - with auxiliary information in the servo track, which contains a continuous address code. The patent EP 0 325 330 describes such a recording medium in which the spatial frequency of the servo track is changed in dependence on the auxiliary information. The patents US 5,999,504 and EP 1 066 628 describe an embodiment in which the phase of the wobble signal is changed abruptly as a function of the auxiliary information.

Since current information recording and / or reproducing apparatuses have to accept an ever-increasing number of different recording media having different recording methods, recording speeds and recording materials, different recording parameters specific to each medium are required for recording. For this reason, in certain embodiments, the auxiliary information already stored in the servo track at the time of delivery of the recording medium is extended by a control code corresponding to that for this contains write medium specified write parameters. The EP 0 397 238 claims, for example, a record carrier in which the auxiliary information consisting of address code and control code is recorded in the preformed track by means of a preformed track modulation including a radial sinusoidal modulation by either track wobble or track width variation.

A disadvantage of a change in the spatial frequency of the servo track turns out that the data rate of the auxiliary information that can be incorporated into the track modulation is considerably limited by the requirement of the least possible influence on the data signal to be recorded. In the methods that change the phase of the wobble signal abruptly ( US 5,999,504 and EP 1 066 628 ), kinks occur in the wobble signal, resulting in a significant increase in the claimed bandwidth. A disadvantage of such methods is the influencing of the main data signal to be recorded (main data pits), since a high wobble frequency results at a high auxiliary data rate, so that the upper frequency range of the modulated wobble signal overlaps the lower frequency range of the main data signal.

Therefore have been used in high density optical recording media for pre-recording auxiliary information that is not based on a modulation of the servo track, but by in or executed outside the servo track arranged pre-pits are.

The US 6,611,489 describes a recording medium having a servo track which has no track bow and is interrupted in certain areas (also referred to as "pre-pit areas"). In these areas, which are not intended for data recording, pre-pits having similar dimensions as the main data pits to be recorded in the servo track or in the land track are preformed. The pre-pits are arranged in the pre-pit area alternately on the extension of the boundary line between servo track and land track, so that occur on both sides of the servo track center or the land track center pre-pits, with a simultaneous occurrence of pre-pits is excluded on directly adjacent borderlines. Since the synchronization of the rotational speed of the recording medium can be done only in the pre-pit areas, which can be detrimental in case of disturbances, leads DE 697 27 710 in addition to US 6,611,489 a recording medium with preformed wobble of the servo track.

For the recording media of US 6,611,489 and the DE 697 27 710 Due to the interruption of the servo track in the pre-pit areas no data recording is possible, resulting in a loss of storage capacity. Probably for this reason leads the US 6,600,711 Pre-pits in the continuos preformed servo track, wherein the pre-pits are arranged in the middle between the land track and the adjacent servo track at predetermined intervals of the same length. These intervals correspond to the length of a recording sector of the main data pits. The pre-pits, due to their dimensions which are similar to the dimensions of the main data pits and thus have a width similar to the land or servo track, can not be arranged alternately to the center of the servo track, otherwise overlaps would result. These overlaps would lead to crosstalk problems that could significantly disrupt the evaluation of the pre-pits. For this reason, the pre-pit sequence for these products is placed only on the side of the servo track closest to the pre-pit sequence in the radial direction. Due to the permanently one-sided arrangement of the pre-pits with respect to the track center, a DC component is produced in the tracking error signal, which is responsible for a permanent error deviation of the beam guiding device of the information recording and / or reproducing apparatus used.

Furthermore the problem arises that the one generated by the optical scanner Data signal experiences a significant influence by the pre-pits, because they protrude considerably into the servo track and thus the width noticeably reduce the servo track in the pre-pit areas.

Task and inventive solution

task The present invention is therefore to provide a technical teaching, with the above-mentioned and other disadvantages the state of the art with the greatest possible Compatibility with existing recording media so far as possible can be avoided.

These The object is achieved by a recording medium, a method and a Apparatus for its production and a method and a device for writing and / or reading information on such or such from such a recording medium according to any one of the independent ones Claims solved.

To preferred developments of the invention are the subject of the dependent claims.

A recording medium according to the invention comprises a servo track or array of servo tracks suitable for guiding a scanning beam or a plurality of scanning beams of an information recording and / or reproducing apparatus and at least in sections for forming, displaying or storing main data. The servo track or the arrangement of servo tracks contains, at least in sections, a wobble signal which contains period ranges of a first signal with a period duration T ₀ and half-period ranges of a second signal. In this case half-period regions of the second signal are inserted between the periods of the first signal.

in this connection it can be a substantially spiral or a concentric track or an array of tracks act. This track or tracks do not necessarily have to throughout for education or presentation or storage of main data in the form of so-called main data pits usable. This formation, presentation or storage of main data takes place by a defined local change of at least one physical property of at least one material in such a Track or in the tracks. Preferably, this is the Reflection and / or transmission behavior of certain areas the track or the tracks.

The realization of the present invention can also be carried out by means of a device for producing a recording medium according to the invention with an optical device for recording a servo track by means of a light beam on a master plate. Here, the optical device includes a modulator for generating the modulated light beam, and the modulator is controlled by a signal generator which generates a control signal corresponding to a wobble signal containing period ranges of a first signal having a period T ₀ and half period ranges of a second signal, wherein between Periodic ranges of the first signal Half-period ranges of the second signal are inserted.

The realization of the present invention may also be accomplished by a method of manufacturing a recording medium using an optical device for recording a servo track by means of a light beam onto a master disk, and wherein the optical device includes a modulator for generating the modulated light beam and the modulator is controlled by a signal generator which generates a control signal corresponding to a wobble signal containing the periodic regions of a first signal with a period T ₀ and half-period portions of a second signal, which are inserted between the period sections of the first signal half-period portions of the second signal.

The implementation of the present invention can also be carried out by means of a device for recording and / or reproducing information on or from a recording medium, with an optical device for recording main data pits in a servo track and / or for reproducing main data from this servo track, said device comprising a group of detectors, of which a wobble signal is derived, containing the period of regions of a first signal with a period T ₀ and half-period portions of a second signal, being inserted between the period sections of the first signal half-period portions of the second signal.

The implementation of the present invention can also be carried out by means of a method for recording and / or reproducing information on or from a recording medium, wherein an optical device for recording main data pits in a servo track and / or for playback of main data is used by this servo track, and in which a device is used which contains a group of detectors from which a wobble signal is derived, which contains periods of a first signal with a period T ₀ and half period ranges of a second signal, wherein between the period ranges of first signal half-period ranges of the second signal are inserted.

embodiments the invention

following For preferred developments of the invention will be described.

A further development of the recording medium according to the invention is preferred in which half-period regions of the second signal inserted between the periods of the first signal occur at least partially in pairs. This has the advantage, inter alia, that these paired half-period regions can be arranged in such a way that the integration of the second signal within these pairwise occurring half-period ranges yields zero. By the expression "at least partially" it is meant that the half-period ranges, depending on the embodiment of the invention, are continuous or only in sections can occur in pairs.

Further preferred is a development of the recording medium according to the invention, in which the period of the second signal is twice the predetermined period T _{0 of} the first signal. This has the advantage, inter alia, that a clock signal can be derived in a particularly simple way from a corresponding wobble signal.

Farther preferred is a development of the invention Recording medium in which episodes of paired Half period ranges of the second signal are the binary values ("0" or "1") of an auxiliary data signal by different sequences of period ranges and half-period ranges encode. This will u. a. the detection of the binary Values simplified or facilitated.

To Furthermore, preference is given to a development of the invention Recording medium in which the number of half-period ranges of the second signal in the sequence of half-period ranges for the binary value "0" of the auxiliary data signal and in the sequence of half-period ranges for the binary Value "1" of the auxiliary data signal is identical.

To Furthermore, preference is given to a development of the invention Recording medium, wherein the auxiliary signal at least one synchronization character and in which the number of half-period ranges of second signal in the sequence of half-period ranges for such a synchronization mark of the auxiliary data signal is different is the number of half-period ranges in the sequence of half-period ranges for the binary value "0" of the Auxiliary data signal and in the sequence of half-period ranges for the binary value "1" of the auxiliary data signal.

To Furthermore, preference is given to a development of the invention Recording medium in which the sequence of half-period ranges for at least one synchronization character of the auxiliary data signal and the sequence of half-period ranges for the binary Value "0" of the auxiliary data signal and the sequence of half period ranges for the binary value "1" of the Auxiliary data signal each having a half period range of the second Signal begins.

To Furthermore, preference is given to a development of the invention Recording medium in which the amplitude of the second signal in the half-period ranges versus the amplitude of the first signal in the period ranges is changed so that no or no noticeable sudden change in slope and / or no or no noticeable sudden change in value arises in the wobble signal. This will cause the spectral properties the corresponding signals also in the sense of a lighter or better Detectability improved. Under an unstoppable or barely "noticeable" leap Therefore, these signals should be understood as all signal curves which are to be improved in the context of the present Invention essential or relevant spectral properties contribute to the corresponding signals.

A further development of the recording medium according to the invention is preferred in which the first signal is DC-free in the period ranges and in which the paired half-period regions of the second signal are arranged such that the integration of the second signal over the half-period regions of this pair yields zero. In this context, the terms "DC-free" and "zero-result" should also be understood to mean signal characteristics in which these criteria are approximately fulfilled. It is important above all that the advantages associated with these signal properties are achieved, namely, that the mean DC component of the wobble signal and thus the mean error signal, which results in the guidance of the scanning beams in the middle of the servo track, are kept permanently at zero or near zero and that, as a consequence, there is no or no significant impact on the beam due to the insertion of half-period ranges ( 21 ) of the second signal.

Also preferred is a development of the recording medium according to the invention, which is characterized in that with the same coding length M by selecting an arbitrary, for the Hilfsdatenbits and the synchronization character same number N of period ranges of the first signal to the M units of length of the period T _0th be added, the bit length is changed so that the amount of the spectrum of the wobble signal falls below a previously defined threshold at least one frequency.

In addition, a further development of the recording medium according to the invention is preferred in which the first signal is sinusoidal or cosinusoidal in the period ranges and, in the half-period ranges the second signal is piecewise sinusoidal or cosinusoidal, the second signal being equal to the first signal in the areas where it is below a predefined threshold in magnitude, and in the areas where it is in magnitude above a predefined threshold , an amplitude and a period that are different from the first signal, wherein the amplitude and the period are selected so that no (noticeable) sudden change in slope and / or no (noticeable) sudden change in value occur in the wobble signal.

To Furthermore, preference is given to a development of the invention Recording medium, in which the auxiliary data signal, that of the sequence is assigned to period ranges and half-period ranges, application data and / or control data and / or safety data.

Some preferred developments of inventive devices for producing a recording medium according to the invention generate a wobble signal having features according to one of the claims 2 to 12.

at some preferred developments of the invention Process for the preparation of inventive Recording media becomes a wobble signal with features after a of claims 2 to 12 generates.

Some preferred developments of the invention Device for recording and / or reproducing information generate a wobble signal having features according to one of the claims 2 to 12.

Farther preferred is a device for recording and / or playback Information in which the wobble signal decoder decoding a decoder the auxiliary data signal is supplied, wherein the decoder for generating a speed control signal for the Rotary unit of the information recording and / or reproducing apparatus by producing an oscillator signal resulting from the wobble signal by means of a comparator circuit and an edge-controlled time measuring unit is derived, is designed.

Farther preferred is a device for recording and / or playback of information where the decoder is a subtraction circuit to form a difference signal representing the difference of the comparator output signal and the oscillator signal, involves using a discrete correlation, where the difference signal for the synchronization character, the auxiliary data bit = "0" and the auxiliary data bit = "1" is used, the synchronization character, the auxiliary data bit = "0" and to generate the auxiliary data bit = "1".

Some preferred developments of the invention Method for recording and / or reproducing information use a wobble signal having features according to any of the claims 2 to 12.

Farther preferred is a method according to the invention for recording and / or reproducing information, in which the wobble signal to a decoder for decoding the auxiliary data signal is supplied, wherein the decoder for generating a speed control signal for the turntable of the information recording and / or Reproducing apparatus by producing an oscillator signal, from the wobble signal by means of a comparator circuit and a edge-controlled time measuring unit is derived, designed is.

Farther preferred is a method according to the invention for recording and / or reproducing information, in which the decoder has a subtraction circuit for forming a difference signal, that is the difference of the comparator output signal and the oscillator signal involves, by means of a discrete correlation, where the difference signal for the synchronization character, the auxiliary data bit = "0" and the auxiliary data bit = "1", the synchronization character, the auxiliary data bit = "0" and that auxiliary data bit = "1" to produce.

Further Advantages, features and applications of the present Invention will become apparent from the following description in conjunction with the figures.

1a . 1b and 1c represent an exemplary embodiment of the wobble signal, which is the coding of the binary auxiliary data bits ( 1a . 1b ) and the auxiliary data synchronization character ( 1c ) contains.

2a and 2 B represent embodiments of smoothed wobble doubles with low or fe lend slope jumps.

3 illustrates an embodiment of the information recording and / or reproducing method according to the invention, which uses the recording medium according to the invention.

4a . 4b and 4c provide signals for an embodiment of a decoder ( 37 ) for the auxiliary data signal.

5a and 5b represent the range of auxiliary data bits coded in the prior art at a bit length of 40 periods T ₀ .

6a and 6b represent the spectrum of auxiliary data bits coded in the prior art at a bit length of 80 periods T ₀ .

7a and 7b represent the spectrum of the auxiliary data bits, which according to an embodiment of the invention without smoothing (with pitch jump) of the wobble signal ( 22 ) are coded at a bit length of 40 periods T ₀ .

8a and 8b represent the spectrum of the auxiliary data bits, which according to an embodiment of the invention without smoothing (with pitch jump) of the wobble signal ( 22 ) are coded at a bit length of 80 periods T ₀ .

9a and 9b represent the spectrum of the auxiliary data bits, which according to an embodiment of the invention with smoothing (without slope jump) of the wobble signal ( 22 ) are coded at a bit length of 40 periods T ₀ .

10a and 10b represent the spectrum of the auxiliary data bits, which according to an embodiment of the invention with smoothing (without slope jump) of the wobble signal ( 22 ) are coded at a bit length of 80 periods T ₀ .

11 shows an embodiment for the decoder ( 37 ) of the auxiliary data signal.

12 shows an embodiment of the device for producing the master plate ( 61 ), which is used as duplicate original of the recording medium according to the invention ( 1 ) can be used.

13a and 13b set the difference signal ( 42 ) for the auxiliary data bit = "0" ( 13a ) and the discrete correlation of this difference signal with itself ( 13b ).

14a and 14b set the difference signal ( 42 ) for the auxiliary data bit = "1" ( 14a ) and the discrete correlation of this difference signal with itself ( 14b ).

15a and 15b set the difference signal ( 42 ) for the synchronization character ( 15a ) and the discrete correlation of this difference signal with itself ( 15b ).

16a . 16b and 16c represent the discrete correlation of the difference signals for the auxiliary data bit = "0" and the auxiliary data bit = "1" ( 16a ), the discrete correlation of the difference signals for the auxiliary data bit = "0" and the synchronization character ( 16b ) and the discrete correlation of the difference signals for the auxiliary data bit = "1" and the synchronization character ( 16c ).

A preferred embodiment of a recording medium according to the invention comprises an array of servo tracks, which are suitable for guiding a scanning laser beam and which comprises a wobble signal for encoding an auxiliary signal according to one of the 1a , b, c included. This wobble signal usually consists of period ranges ( 20 ) of a first DC-free signal having a predetermined period T ₀ . For pre-recording the auxiliary data signal, between the period ranges ( 20 ) of the first signal pairs occurring half-period ranges ( 21 ) of a second signal having twice the predetermined period T ₀ inserted. The pairwise occurring half-period ranges ( 21 ) arranged so that the integration of the second signal within these paired half-period ranges ( 21 ) Returns zero.

The binary values ("0" or "1") are replaced by a sequence of paired half-periods areas ( 21 ) are coded such that the time sequence of the half-period ranges ( 21 ) for the binary value "0" different from the time sequence of the half-period ranges ( 21 ) of the binary value is "1". To avoid the transition from the period ranges ( 20 ) of the first signal to the half-period range ( 21 ) of the second signal without (or without noticeable) sudden change in pitch in the wobble signal, the amplitude of the second signal can be suitably adapted to the amplitude of the first signal.

Due to the DC-freedom of the first signal and the property that the integration of the second signal within a pair of half-period ranges ( 21 ) Returns zero, the average DC component of the wobble signal and thus the average error signal, which results in the guidance of the scanning beams in the middle of the servo track, is permanently kept at zero. As a result, no beam retardation is caused by the insertion of half-period ranges ( 21 ) of the second signal.

Since the wobble signal is composed exclusively of oscillations of the period T ₀ and the period 2T ₀ , a constant clock signal of the period T ₀ can be derived from the wobble signal. For this purpose, a control circuit with edge-controlled time measurement is preferably used, which controls the clock signal in the form of a controlled oscillator signal as a function of the zero crossings of the wobble signal. By means of this clock signal of the period T _o , whose reciprocal is related to the main data bit rate at the intended linear writing speed, a control signal can be derived, which controls the rotational speed of the recording medium.

Based on 3 For one embodiment, the information recording and / or reproducing method will be described which comprises the recording medium (FIG. 1 ) used. The recording medium ( 1 ) has an array of servo tracks which are suitable for guiding a scanning laser beam and which generate a wobble signal ( 22 ) for encoding an auxiliary signal according to one of 1a , b, c included.

The turntable ( 32 ) in 3 turns the recording medium ( 1 ) in response to a speed control signal supplied by the speed control unit ( 36 ) is produced. The speed of the recording medium ( 1 ) may be set so as to be a predetermined constant linear velocity or a predetermined constant angular velocity in the recording and / or reproduction of the main optical scanning beam (FIG. 5 ) and the pilot scanning beams ( 6 ). The optical unit ( 30 ) generates the main scanning beam ( 5 ) and two pilot scanning beams ( 6 ), bundles them at the information level of the recording medium ( 1 ) and forms the scanning beams on a group of photodetectors ( 34 ). The photodetector group consists of pilot beam detectors for the pilot scanning beams ( 6 ) and, for example, a four-divided main beam detector for the main scanning beam ( 5 ). The incident on the individual detector surfaces light intensity is converted into electrical signals that are available separately for each surface element and to the decoder ( 37 ) for the auxiliary data and to the decoder ( 38 ) for recorded main data pits. The decoder ( 37 ) additionally determines the speed control signal from the wobble signal ( 22 ) and passes this to the speed control unit ( 36 ). The central control unit ( 39 ), which may consist of a conventional microcomputer and / or a signal processing computer, derives from the signals of the pilot beam and main beam detectors suitable control signals for radial positioning and focusing of the optical unit ( 30 ) in a conventional manner, as for example in "Terry W. McDaniel, Randall H. Victora: Handbook of Magneto-Optical Data Recording, Noyes Publications, Westwood, New York" is described. The control signals are sent to the position and focus control unit ( 35 ), which is a movable lens of the optical unit ( 30 ) horizontally for radial tracking and vertical for focus tracking. The intensity of the monochromatic light beam of the optical unit ( 30 ) must be above a certain switching threshold for information recording and for information reproduction below this switching threshold. The corresponding intensity control is done via the light control unit ( 33 ) from the central control unit ( 39 ) is controllable.

The 1 show an exemplary embodiment of the wobble signal ( 22 ) containing the encoding of a binary auxiliary data signal according to the invention. For the auxiliary data signal, application data, safety data and control data are considered.

• • Instruktionen zur Handhabung des Aufzeichnungsmediums,
• • werbetechnische Hinweise des Herstellers,
• • zur Unterhaltung oder Information dienende Bild- und/oder Toraufnahmen
• • und dergleichen

beinhalten, zu verstehen.The application data includes, for example, pre-recorded information, for example

• Instructions for handling the recording medium,
• • advertising information of the manufacturer,
• • for entertainment or information serving image and / or Toraufnahmen
• • and the same

involve understanding.

• • Adressierung
• • Intensitätskennwerte der Lichtquelle für die Informationsaufzeichnung
• • Kennwerte für die Impulsfolgen der Lichtquelle für die Informationsaufzeichnung
• • Kenngrößen der Aufzeichnungsschichten des Aufzeichnungsmediums
• • Kennwerte für die Aufzeichnungsgeschwindigkeit
• • Startadresse des Aufzeichnungsbereichs
• • Stoppadresse des Aufzeichnungsbereichs
• • und dergleichen

herangezogen werden.As control data, for example

• • addressing
• • Intensity characteristics of the light source for information recording
• • Characteristic values for the pulse sequences of the light source for the information recording
• • Characteristics of the recording layers of the recording medium
• • Characteristics for the recording speed
• • Start address of the recording area
• • Stop address of the recording area
• • and the same

be used.

• • Schlüsseldaten zur Berechtigung des Aufzeichnungsmediums, bestimmte Programmgruppen eines Herstellers aufzeichnen zu dürfen
• • Herstellersignatur
• • und dergleichen

fallen.For example, in the class of security data

• • Key data for authorizing the recording medium to be able to record certain program groups of a manufacturer
• • Manufacturer's signature
• • and the same

fall.

So far the user does not erase or re-record the auxiliary data signal can be, this information comes a high security relevant Meaning too. Over the range of the specified exemplary Fields of application is for the expert a variety given by further applications

The Auxiliary data signal preferably consists of a sequence of binary Values (auxiliary data bits) assigned to a binary number code could be. A binary number code is common composed of the logical elements "0" and "1".

For example, addresses that consist of four decimal places according to the invention in the wobble signal ( 22 ), each decimal point can be converted to a 4-bit binary coded decimal (BCD) binary code. Thus, each address consists of a total of 4 (decimal places) x 4 bits = 16 bits which can be combined to form a serial data frame. There is the additional possibility, in addition to the addresses, also application data, safety data and control data in the wobble signal ( 22 ). Consequently, the data frame can be extended by this information, whereby redundant bits can still be inserted into the data frame for error protection.

The data frame thus obtained is bitwise serially in the wobble signal ( 22 ) according to one of 1a , b, c coded. In this case, for the data elements ("0", "1", "Sync" = synchronization character), the respective characteristic area in the wobble signal ( 22 ) in the 1a , b, c delimited by the two vertical dotted lines. Within this characteristic range, which has the same length for all data elements ("0", "1", "sync"), a sequence of period ranges typical of the respective data element ( 20 ) of the first DC-free signal having a predetermined period T ₀ and the preferably occurring in pairs half-period ranges ( 21 ) of a second signal which is twice the predetermined period T ₀ . The signal course within the half-period ranges ( 21 ) is alternately complementary, ie a pair of half periods ( 21 ) consists of a negative course of the second signal and a positive course of this signal as it is in the 1a , b, c is shown. Consequently, the mean disappears over a pair of two consecutive half periods ( 21 ), which results from the integration of the second signal within this half-period pair. Due to the DC-freedom of the first signal in the period ranges ( 20 ) and the second signal in a pair of half-period regions ( 21 ) is the wobble signal ( 22 ) also DC-free, so that the error-free tracking of the optical scanning by the position and focus control unit ( 35 ).

According to 1a and 1b the auxiliary data bits "0" and "1" are respectively represented by two pairs of half-period ranges ( 21 ) in the wobble signal ( 22 ), wherein in the characterizing range the sequence of period ranges ( 20 ) of the first signal and half-period ranges ( 21 ) of the second signal is different. To mark the beginning of the auxiliary data frame by a synchronization character, for example, the in 1c shown "sync" sequence, which are different from the sequences of Auxiliary data bits "0" and "1" uniquely different. Thus, the detection of the beginning of the frame, for example, the first entry into the data stream or after the intentional or erroneous skipping of data, allows.

Outside the identically long identifying areas that are in the 1a , b, c are marked by the vertical dotted lines, any number of period ranges ( 20 ) of the first signal in the wobble signal ( 22 ).

For the spectral behavior of the wobble signal ( 22 ) is the shape of the second signal in the half-period ranges ( 21 ) is crucial. Particularly favorable in particular in the 2a and 2 B shown embodiments of a waveform in which the wobble signal ( 22 ) has no (noticeable) sudden changes in slope and no sudden changes in value. For this purpose, the second signal within a half-period range ( 21 ) are composed by three signal parts. In the space regions 0 ≦ x <T ₁ and 2 × T ₀ -T ₁ ≦ x <2 × T ₀ , the second signal is identical to the first signal, while the second signal is in the spatial range T ₁ ≦ x <2 × T ₀ - T _{1 is} different from the first signal. Here, the second signal has a different period and a different amplitude to the first signal.

The 2a and 2 B show two embodiments in which the first signal is sinusoidal and the second signal piecewise sinusoidal or cosinusoidal. The second signal is in the space regions 0 ≤ x <T ₁ and 2 · T ₀ - T ₁ ≤ x <2 · T ₀ with s _A (x) and in the space range T ₁ ≤ x <2 · T ₀ - T ₁ with s _B (x), where x indicates the path on the middle line of symmetry of the servo track. Due to the requirement that no (or no noticeable) sudden changes in slope and no (or no noticeable) sudden value changes in the wobble signal ( 22 ), the mathematical equations apply to the transition from the signal s _A (x) to the signal s _B (x) (exactly or at least to a certain extent): s A (T 1 ) = Sin (2πT 1 / T 0 ) = s B (T 1 ) = A B Cos (2π (T 0 - T 1 ) / T B )

In this case, T _{B denote} the desired period duration and A _B the desired amplitude of s _B (x). By substituting the equations, the period T _B results from the numerical resolution of the equation:

For the amplitude A _B , one then obtains:

For the waveform in 2a became the parameters switching threshold: s _A (T ₁ ) = 0.85 Switchover points s _A (x) to s _B (x): T _{A → B} = 0.1617 T ₀ Switchover points s _B (x) to s _A (x): T _{B → A} = 0.8383 T ₀ Period of s _B (x): T _B = 2.2438 T ₀ Amplitude of s _B (x): A _B = 1.456 used.

For the waveform in 2 B became the parameters switching threshold: s _A (T ₁ ) = 0.5 Switchover points s _A (x) to s _B (x): T _{A → B} = 0.0833 T ₀ Switchover points s _B (x) to s _A (x): T _{B → A} = 0.9166 T ₀ Period of s _B (x): T _B = 2.0247 T ₀ Amplitude of s _B (x): A _B = 1.8234 used.

An important advantage of the waveforms according to the 2a and 2 B compared to the signal forms known from the prior art can be seen that in this embodiment of the invention, a lower signal bandwidth is claimed and that in the production of a corresponding servo track lower demands on the wobble generator and the impression quality must be made.

In the 2a , b is shown as an example only the case for the positive course of the second signal. In the case of the negative gradient, the switching threshold value s _A (T ₁ ) and the amplitude A _{B are} also negative.

The 5a , Federation 6a , b show the spectra of the wobble signal according to the prior art, as shown for example in the US 5,999,504 and the EP 1 066 628 is described. The spectrum in the 5a , b is determined for a bit length of 40 periods T ₀ , which consist of 8 periods T ₀ for encoding the respective auxiliary data bits and then 32 periods T _{0 of} the unencoded wobble signal. The spectrum in the 6a , b is determined for a bit length of 80 periods T ₀ , which consist of 8 periods T ₀ for encoding the respective Hilfsdatenbits and subsequent 72 periods T _{0 of} the unencoded wobble signal. The distance of the five vertical grid lines in the 5a , Federation 6a , b corresponds to the reciprocal of the period T ₀ . The spectral line for the reciprocal of the period T ₀ is outstanding due to the dominance of this oscillation with the frequency 1 / T ₀ .

In the 7a , Federation 8a , b are the spectra of the non-smoothed wobble signal according to the invention ( 22 ), which at constant amplitude has sudden changes in slope in the transition from the first to the second signal. The spectrum in the 7a , b is for a bit length of 40 periods T ₀ (comparable to the 5a , b), which consist of 9 periods T ₀ (= coding length) for coding the respective Hilfsdatenbits and subsequent 31 periods T _{0 of} the first signal. The spectrum in the 8a , b is for a bit length of 80 periods T ₀ (comparable to the 6a , b), which consist of 9 periods T ₀ (= coding length) for coding the respective auxiliary data bit and subsequent 71 periods T _{0 of} the first signal.

The improvement over the prior art ( 5a , Federation 6a , b) is recognizable because in the spectra ( 7a , Federation 8a , b) sets a faster amplitude drop as a function of the frequency.

In the 9a , Federation 10a , b are the spectra of an example embodiment of the invention smoothed wobble signal ( 22 ), which has an adjusted amplitude according to the 2a , b shown embodiments and thus has no sudden changes in slope. The spectrum in the 9a , b is for a bit length of 40 periods T ₀ (comparable to 5a , b), which consist of 9 periods T ₀ (= coding length) for coding the respective Hilfsdatenbits and subsequent 31 periods T _{0 of} the first signal. The spectrum in the 10a , b is for a bit length of 80 periods T ₀ (comparable to the 6a , b), which consist of 9 periods T ₀ (= coding length) for coding the respective auxiliary data bit and subsequent 71 periods T _{0 of} the first signal.

The improvement over the prior art ( 5a , Federation 6a , b) is clearly visible, since in the spectra ( 9a , Federation 10a , b) sets a much faster amplitude drop as a function of the frequency.

From the spectral investigations, in particular on the 9a , Federation 10a , b, it can be seen that the decrease in the spectrum as a function of the frequency can be increased by the bit length with the coding length M remaining the same, ie the characteristic range in the wobble signal (FIG. 22 ), which in the 1a , b, c is delimited by the two vertical dotted lines (here M = 9T ₀ ) by adding an arbitrary number N of period ranges (for the auxiliary data bits and the synchronization character) ( 20 ) of the first signal is increased. Consequently, the influence can thereby tion of the main data signal to be recorded (main data pits) can be further reduced since the overlap of the upper frequency range of the modulated wobble signal ( 22 ) becomes even lower with the lower frequency range of the main data signal. In particular, it is possible to define a threshold below which the amount of the spectrum of the wobble signal ( 22 ) can be held by a suitable choice of the number N.

An embodiment of a decoder ( 37 ) for recovering the auxiliary data from the wobble signal ( 22 ) is in 11 shown. When correctly guided, the symmetry line of the photodetector group ( 34 ) just above the middle line of symmetry of the optical image of the servo track.

With correct tracking, the light components of the main scanning beam ( 5 ) or the pilot scanning beams ( 6 ) is identical on both sides of the middle line of symmetry of the servo track. The signals of the photodetectors group ( 34 ) of the recording and / or reproducing apparatus can be linked to one another such that essentially the difference of the two-sided light components is processed. When the tracking of the main scanning beam ( 5 ) or the pilot scanning beams ( 6 ) is performed with a time constant which is substantially greater than the period T ₀ , then the tracking can not follow the Spurwobble. By the difference-linking of the signals of the photodetector group ( 34 ) produces the wobble signal ( 22 ).

The wobble signal ( 22 ) the comparator circuit ( 50 ), which assigns the logical value "1" to the signal values above a following threshold and the logical value "0" below this threshold. To DC voltage fluctuations, which occur due to unavoidable tolerances of the recording medium and the position of the zero crossings of the wobble signal ( 22 ), the comparator threshold is reduced by means of the low-pass circuit ( 53 ) readjusted. At the output of the comparator circuit, the signal ( 40 ), which is in 4 for the sync character "Sync" ( 4c ), for the auxiliary data bit = "0" ( 4a ) and for the auxiliary data bit = "1" ( 4b ) is shown.

The signal ( 40 ) and the binary signal ( 41 ) generated by the voltage-controlled oscillator ( 58 ) is applied to the inputs of the edge-triggered time measuring unit ( 51 ). The task of the time measurement unit ( 51 ) is at each positive edge of the signal ( 40 ), ie at the transition from the logical value "0" of the signal ( 40 ) at the logical value "1", and at each negative edge, ie at the transition from the logical value "1" of the signal ( 40 ) to the logical value "0", the time between the respective edge of the signal ( 40 ) and the nearest positive edge of the binary oscillator signal ( 41 ) to investigate. If the relevant edge of the signal ( 40 ) in time before the associated positive edge of the signal ( 41 ), the determined time difference is calculated as a proportional negative control voltage value at the output of the time measuring unit ( 51 ). In the event that the edge of the signal ( 40 ) behind the associated positive edge of the signal ( 41 ), the determined time difference is output as a positive control voltage value proportional thereto. With the help of the control voltage, which for reasons of stability with the help of the low pass ( 52 ), the frequency or the period of the signal ( 40 ) are regulated in such a way that they are as precisely as possible with the period T _{0 of} the first signal which is in the period ranges ( 20 ), matches.

Because the signal ( 40 ) usually the period T ₀ and only in the rarely occurring half-period ranges ( 21 ) has the period 2T ₀ , the time constant of the low-pass filter ( 52 ) are chosen such that they example, on the order of ten times the period T ₀ . Thus, the change of the period duration in the signal ( 40 ) during the half-period periods ( 21 ) does not affect the stability of the oscillator signal ( 41 ), from which by means of the speed control unit ( 36 ) the control signal for the turntable ( 32 ) of the recording medium ( 1 ) can be derived.

With the help of the subtraction circuit ( 54 ), which can be realized by a logical exclusive-OR circuit, the difference of the signal ( 40 ) and the oscillator signal ( 41 ) educated. The difference signal ( 42 ) located at the output of the subtraction circuit ( 54 ) has for each component of the auxiliary data signal "Sync" ( 4c ), Auxiliary data bit = "0" ( 4a ) and auxiliary data bit = "1" ( 4b ) a clearly distinguishable waveform.

To recognize the waveform for the synchronization symbol "Sync", the circuit ( 55 ), which determines the discrete correlation between that in the circuit ( 55 ) stored binary nominal waveform for the synchronization character and the course of the binary difference signal ( 42 ). If there is sufficient agreement, an indication signal is output at the output of the circuit ( 55 ) generated.

To detect the signal curve for the auxiliary data bit = "0", the circuit ( 56 ), which determines the discrete correlation between that in the circuit ( 56 ) stored binary nominal waveform for the auxiliary data bit = "0" and the course of the binary difference signal ( 42 ). If there is sufficient agreement, an indication signal is output at the output of the circuit ( 56 ) generated.

To recognize the signal curve for the auxiliary data bit = "1", the circuit ( 57 ), which determines the discrete correlation between that in the circuit ( 57 ) stored binary desired waveform for the auxiliary data bit = "1" and the course of the binary difference signal ( 42 ). If there is sufficient agreement, an indication signal is output at the output of the circuit ( 57 ) generated.

The procedure of the discrete correlation is supposed to be based on the 13a , b, 14a , b, 15a , b and the 16a , b, c are explained. The difference signal ( 42 ), which is for the auxiliary data bit = "0" in 13a , for the auxiliary data bit = "1" is in 14b and for the synchronization mark is in 15a is discretized so that samples are taken out of this signal in the form of a sequence of numbers at equidistant intervals. By means of this process, the discrete difference _signal s _diff (nT ₀ / N _d ) is formed from the continuous difference _signal s _Diff (x), where N _{d is} the number of samples with respect to the period range ( 20 ) of the first signal. The discrete correlation S _Korr1,2 (kT ₀ / N _d ) of two different discrete difference _signals s _Diff1 (nT ₀ / N _d ) and s _Diff2 (nT ₀ / N _d ) is then defined by the relationship:

Accordingly, the discrete correlation S _Korr1 (kT ₀ / N _d ) of the discrete difference _signal s _Diff1 (nT ₀ / N _d ) with itself is defined by the relationship:

Since the difference signal ( 42 ) assumes only binary values, the multiplication in the execution of the discrete correlation can be simplified by a logical AND operation.

In 13b is the course of the discrete correlation of the difference signal with itself for the auxiliary data bit = "0", in 14b is the course of the discrete correlation of the difference signal with itself for the auxiliary data bit = "1" and in 15b shows the course of the discrete correlation of the difference signal with itself for the synchronization character. Essential for the decision as to which auxiliary data bit or whether the synchronization character is present is the value of the discrete correlation at the zero point, the zero point being determined by the first edge of the difference signal ( 42 ) is indexed for reference. Out 13b . 14b and 15b the following values of the discrete correlation at the zero point can be seen: Auxiliary data bit = "0" Auxiliary data bit = "1" synchronization character Fig. 13b Fig. 14b Fig. 15b S _Korr0 (0) = 2.4 S _corr1 (0) = 2.4 S _KorrSync (0) = 3.2

For unambiguous detectability, the requirement is that the values of the discrete correlation of the respective difference signal with itself at the zero point be significantly greater than the values of the discrete correlation of different difference signals. In 16a is the course of the discrete correlation of the difference signal for the auxiliary data bit = "0" with the difference signal for the auxiliary data bit = "1", in 16b is the course of the discrete correlation of the difference signal for the auxiliary data bit = "0" with the difference signal for the synchronization character and in 16c the course of the discrete correlation of the difference signal for the auxiliary data bit = "1" is shown with the difference signal for the synchronization character. Out 16a . 16b and 16c the following values of the discrete correlation at the zero point can be seen: Auxiliary data bit = "0" Auxiliary data bit = "0" Auxiliary data bit = "1" Auxiliary data bit = "1" synchronization character synchronization character Fig. 16a Fig. 16b Fig. 16b S _Cor0.1 (0) = 0.8 S _{Korr0, Sync} (0) = 0.8 S _{corr1, sync} (0) = 0.8

It can be seen that the value of the discrete correlation of the respective difference signal (for the auxiliary data bit = "0", for the auxiliary data bit = "1" and for the synchronization character) with itself in the zero point is significantly greater than 2, while the values of the discrete Correlation of different differential signals in Zero point are significantly smaller than 1. Therefore, the method of discrete correlation in the circuit ( 55 ), in the circuit ( 56 ) and in the circuit ( 57 ) for unambiguous detectability for the auxiliary data bit = "0", for the auxiliary data bit = "1" and for the synchronization character.

This unambiguous detectability is still present even if due to possible errors in the wobble signal ( 22 ) the difference signal ( 42 ) being affected. In this case as well, where a shift of the zero point by one or more steps T ₀ / N _d to the left or to the right would result in the diagrams of the discrete correlation, the values of the discrete correlation of the respective difference signal are in a sufficiently wide range with itself is significantly greater than the values of the discrete correlation of different differential signals.

In 12 is an embodiment of the generating device for producing the servo track with period ranges ( 20 ) of the first signal and half-period ranges ( 21 ) of the second signal on a master disk ( 61 ).

The monochromatic light source ( 68 ), which can consist of a laser, generates a light beam ( 69 ) having a wavelength approximately equal to the width of the servo track. With the help of the electro-optical modulator ( 66 ), the radial position of the light beam ( 69 ) in response to the control voltage supplied by the signal generator ( 67 ) is generated to the symmetry line of the light beam ( 69 ) alternately to the pivot point of the master plate ( 61 ) or from the pivot point of the master plate ( 61 ) are moved away.

The course of the control voltage at the output of the signal generator ( 67 ) corresponds to the course of the wobble signal ( 22 ) dependent on the auxiliary data signal by the sequence of half-period ranges ( 21 ) of the second signal between the periods ( 20 ) of the first signal is encoded. The by means of the modulator ( 66 ) modulated light beam ( 70 ) is adjusted by means of the movable focus lens ( 64 ) received from the position and focus control unit ( 65 ), to the light spot ( 60 ) focused. With the help of this light spot ( 60 ) is the photoresist with which the surface of the master plate ( 61 ), exposed to produce the required geometry of the servo track.

The thickness of the photoresist should correspond to the depth of the servo track to be generated. The required beam geometry is determined by means of the movable focus lens ( 64 ) in such a way that the light spot ( 60 ) on the surface of the master plate ( 61 ) is adjusted approximately to the width of the servo track. During the exposure process, the focus lens ( 64 ) and the master plate ( 61 ) by means of the turntable ( 62 ) parallel to the focal plane of the light spot ( 60 ) so as to adjust a servo track having a spiral or concentric circular structure or an array of servo tracks. To take into account any unevenness of the master plate, the movable focus lens ( 64 ) by means of the positioning and focus control unit ( 65 ) are always readjusted to achieve a consistent light spot. In a subsequent etching process, the exposed areas of the photoresist are removed and finally the master plate ( 61 ) coated with a reflective layer.

From the master plate ( 61 In combined electroplating and injection molding processes, large numbers of plastic impressions can be produced which are provided with one or more recording layers. However, such techniques for the production of plastic data carriers with a servo track are known to the person skilled in the art and are not the subject matter of the present description.

Even though the invention with reference to embodiments described has been, the invention is not limited to these embodiments limited.

20

Periodenbereiche des ersten Signals

21

Halbperiodenbereiche des zweiten Signals

22

Wobblesignal

1 . 2 :

20

Period ranges of the first signal

21

Half-period ranges of the second signal

22

wobble

1

Aufzeichnungsmedium

5

Hauptabtaststrahl

6

Pilotabtaststrahlen

30

Optische Einheit

32

Dreheinheit für das Aufzeichnungsmedium (1)

33

Licht-Steuereinheit

34

Photodetektoren

35

Positions- und Fokussteuereinheit

36

Drehzahl-Steuerungseinheit

37

Decoder für das Hilfsdatensignal

38

Decoder für aufgezeichnete Hauptdaten-Pits (23)

39

Zentral-Steuereinheit

3 :

1

recording medium

5

Hauptabtaststrahl

6

Pilotabtaststrahlen

30

Optical unit

32

Rotary unit for the recording medium ( 1 )

33

Light-control unit

34

photodetectors

35

Position and focus control unit

36

Speed control unit

37

Decoder for the auxiliary data signal

38

Decoder for recorded main data pits ( 23 )

39

Central control unit

40

Signal nach Komparatorschaltung (50)

41

Oszillator-Signal

42

Differenzsignal

50

Komparatorschaltung mit mitlaufender Komparatorschwelle

51

Flankengesteuerte Zeitmesseinheit

52

Tiefpass

53

Tiefpass

54

Subtraktionsschaltung

55

Sync-Erkennung

56

Hilfsdatenbit = ”0”-Erkennung

57

Hilfsdatenbit = ”1”-Erkennung

58

Spannungsgesteuerter Oszillator

4 . 11 :

40

Signal after comparator circuit ( 50 )

41

Oscillator signal

42

difference signal

50

Comparator circuit with revolving comparator threshold

51

Edge-controlled time measuring unit

52

lowpass

53

lowpass

54

subtraction

55

Sync detection

56

Auxiliary data bit = "0" detection

57

Auxiliary data bit = "1" detection

58

Voltage controlled oscillator

60

Lichtfleck

61

Masterplatte

62

Dreheinheit für Masterplatte (61)

63

Drehzahl-Steuerungseinheit

64

Bewegliche Fokus-Linse

65

Positions- und Fokussteuereinheit

66

Elektro-Optischer Modulator

67

Signalgenerator

68

Monochromatische Lichtquelle

69

Lichtstrahl

70

Modulierter Lichtstrahl

12 :

60

light spot

61

Master plate

62

Rotary unit for master plate ( 61 )

63

Speed control unit

64

Mobile Focus Lens

65

Position and focus control unit

66

Electro-optical modulator

67

signal generator

68

Monochromatic light source

69

beam of light

70

Modulated light beam

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - EP 0325330 [0006]
• US 5999504 [0006, 0008, 0083]
• EP 1066628 [0006, 0008, 0083]
• EP 0397238 [0007]
• - US 6611489 [0010, 0010, 0011]
• - DE 69727710 [0010, 0011]
• - US 6600711 [0011]

Cited non-patent literature

• - "Terry W. McDaniel, Randall H. Victora: Handbook of Magneto-Optical Data Recording, Noyes Publications, Westwood, New York" [0064]

Claims (24)

Recording medium ( 1 ) with a servo track or array of servo tracks suitable for guiding a scanning beam or a plurality of scanning beams of an information recording and / or reproducing apparatus and at least in sections for forming, displaying or storing main data, said servo track or array of servo tracks at least in sections, a wobble signal ( 22 ), characterized in that the wobble signal ( 22 ) Period ranges ( 20 ) of a first signal having a period T ₀ and half-period ranges ( 21 ) of a second signal, wherein between the period ranges ( 20 ) of the first signal half period ranges ( 21 ) of the second signal are inserted. Recording medium ( 1 ) according to claim 1, wherein between the period ranges ( 20 ) of the first signal ( 21 ) of the second signal occur at least partially in pairs. A recording medium according to any one of the preceding claims, wherein the period of the second signal is twice the predetermined period T _{0 of} the first signal. Recording medium according to one of the preceding claims, in which sequences of paired half-period regions ( 21 ) of the second signal, the binary values ("0" or "1") of an auxiliary data signal by different sequences of the period ranges ( 20 ) and half-period ranges ( 21 ) code. Recording medium according to one of the preceding claims, in which the number of half-period regions ( 21 ) of the second signal in the sequence of half-period ranges ( 21 ) for the binary value "0" of the auxiliary data signal and in the sequence of half-period ranges ( 21 ) is identical for the binary value "1" of the auxiliary data signal. Recording medium according to one of the preceding claims, in which the auxiliary signal can contain at least one synchronization character and in which the number of half-period regions ( 21 ) of the second signal in the sequence of half-period ranges ( 21 ) for such a synchronization character of the auxiliary data signal is different from the number of half-period regions ( 21 ) in the sequence of half-period domains ( 21 ) for the binary value "0" of the auxiliary data signal and in the sequence of half-period ranges ( 21 ) for the binary value "1" of the auxiliary data signal. Recording medium according to one of the preceding claims, in which the sequence of half-period regions ( 21 ) for at least one synchronization character of the auxiliary data signal and the sequence of half-period regions ( 21 ) for the binary value "0" of the auxiliary data signal and the sequence of half-period ranges ( 21 ) for the binary value "1" of the auxiliary data signal, each having a half-period range ( 21 ) of the second signal begins. Recording medium according to one of the preceding claims, in which the amplitude of the second signal in the half-period regions ( 21 ) versus the amplitude of the first signal in the period domains ( 20 ) is changed so that no or no noticeable sudden change in slope and / or no or no noticeable sudden change in value in the wobble signal ( 22 ) arises. Recording medium according to one of the preceding claims, in which in the period ranges ( 20 ) the first signal is DC-free and in which the pairwise occurring half-period ranges ( 21 ) of the second signal are arranged such that the integration of the second signal over the half-period regions ( 21 ) of this pair returns zero. Recording medium according to one of the preceding claims, characterized in that, with the coding length M remaining the same, by selecting any number N of period ranges (N) equal to the auxiliary data bits and the synchronization mark ( 20 ) of the first signal, which are added to the M length units of the period T ₀ , the bit length is changed so that the amount of the spectrum of the wobble signal ( 22 ) falls below a previously defined threshold at least one frequency. Recording medium according to one of the preceding claims, characterized in that in the period ranges ( 20 ) the first signal sinusoidal or cosinusoidal and in the half-period regions ( 21 ) the second signal is piecewise sinusoidal or cosinusoidal, wherein the second signal is equal to the first signal in the regions where it is below a predefined threshold in magnitude, and in the Areas in which it is in magnitude above a predefined threshold, an amplitude and a period that are different from the first signal, wherein the amplitude and the period are chosen so that no sudden change in slope and no sudden change in value in Wobblesignal ( 22 ) occur. A recording medium according to any one of the preceding claims, wherein the auxiliary data signal representing the sequence of period domains ( 20 ) and half-period ranges ( 21 ), application data and / or control data and / or security data. Apparatus for producing a recording medium ( 1 ), in particular according to at least one of claims 2 to 12, with a device for recording a servo track by means of a write beam ( 69 ) on a master plate ( 61 ), characterized in that the optical device comprises a modulator ( 66 ) for generating the modulated light beam ( 70 ) and the modulator ( 66 ) from a signal generator ( 67 ) which controls a control signal in accordance with a wobble signal ( 22 ), the period ranges ( 20 ) of a first signal having a period T ₀ and half-period ranges ( 21 ) of a second signal, wherein between the period ranges ( 20 ) of the first signal half period ranges ( 21 ) of the second signal are inserted. Manufacturing apparatus according to claim 13, wherein a wobble signal having features according to any of the claims 2 to 12 is generated. Method for producing a recording medium ( 1 ), in particular according to at least one of claims 1 to 11, in which a device for recording a servo track by means of a write beam ( 69 ) on a master plate ( 61 ), characterized in that the optical device comprises a modulator ( 66 ) for generating the modulated light beam ( 70 ) and the modulator ( 66 ) from a signal generator ( 67 ) which controls a control signal in accordance with a wobble signal ( 22 ), the period ranges ( 20 ) of a first signal having a period T ₀ and half-period ranges ( 21 ) of a second signal, wherein between the period ranges ( 20 ) of the first signal half period ranges ( 21 ) of the second signal are inserted. A manufacturing method according to claim 15, wherein a wobble signal having features according to any of the claims 2 to 12 is generated. Device for recording and / or reproducing information on or from a recording medium ( 1 ), in particular according to one of claims 1 to 11, with an optical device for recording main data pits into a servo track and / or for reproducing main data from this servo track, characterized in that this device comprises a group of detectors ( 34 ), of which a wobble signal ( 22 ), the period ranges ( 20 ) of a first signal having a period T ₀ and half-period ranges ( 21 ) of a second signal, wherein between the period ranges ( 20 ) of the first signal half period ranges ( 21 ) of the second signal are inserted. Apparatus for recording and / or reproducing information according to claim 17, wherein the wobble signal ( 22 ) Has features according to one of claims 2 to 12. Device for recording and / or reproducing information according to one of Claims 17 or 18, in which the wobble signal ( 22 ) a decoder ( 37 ) is supplied for decoding the auxiliary data signal, wherein the decoder ( 37 ) for generating a rotational speed control signal for the rotary unit ( 32 ) of the information recording and / or reproducing apparatus by producing an oscillator signal ( 41 ) derived from the wobble signal ( 22 ) by means of a comparator circuit ( 50 ) and an edge-triggered time measuring unit ( 51 ) is designed. Apparatus for recording and / or reproducing information according to claim 19, wherein the decoder ( 37 ) a subtraction circuit ( 54 ) for forming a difference signal ( 42 ), which is the difference of the comparator output signal ( 40 ) and the oscillator signal ( 41 ) involves, by means of a discrete correlation, in which the difference signal ( 42 ) for the sync character based on the auxiliary data bit = "0" and the auxiliary data bit = "1", the sync character, the auxiliary data bit = "0" and the auxiliary data bit = "1". Method for recording and / or reproducing information on or from a recording medium ( 1 ), in particular according to one of claims 1 to 11, in which an optical device is used for recording main data pits in a servo track and / or for reproducing main data from this servo track, characterized in that a device is used which comprises a group of detectors ( 34 ), of which a wobble signal ( 22 ), the period ranges ( 20 ) of a first signal having a period T ₀ and half-period ranges ( 21 ) of a second signal, wherein between the period ranges ( 20 ) of the first signal half period ranges ( 21 ) of the second signal are inserted. Method for recording and / or reproduction of information with a wobble signal with features after one of claims 2 to 12. Method for recording and / or reproducing information according to one of Claims 21 or 22, in which the wobble signal ( 22 ) a decoder ( 37 ) is supplied for decoding the auxiliary data signal, wherein the decoder ( 37 ) for generating a rotational speed control signal for the rotary unit ( 32 ) of the information recording and / or reproducing apparatus by producing an oscillator signal ( 41 ) derived from the wobble signal ( 22 ) by means of a comparator circuit ( 50 ) and an edge-triggered time measuring unit ( 51 ) is designed. Method for recording and / or reproducing information according to Claim 23, in which the decoder ( 37 ) a subtraction circuit ( 54 ) for forming a difference signal ( 42 ), which is the difference of the comparator output signal ( 40 ) and the oscillator signal ( 41 ) by means of a discrete correlation in which the difference signal ( 42 ) for the sync character based on the auxiliary data bit = "0" and the auxiliary data bit = "1", the sync character, the auxiliary data bit = "0" and the auxiliary data bit = "1".