CZ20003739A3 - Method of storing identification onto a record carrier, device for reading from the carrier and recording onto the carrier and record carrier per se - Google Patents

Abstract

When Storing Disc Identification on a Carrier (1) record containing tracks (4) in which it can be stored information, the disk identification bits are stored on the carrier (1) record diffused. Device for reading record carrier (1) includes a system for detecting and reading information present on the record carrier (1), wherein the system includes detection means for detecting disc identification on a carrier (1) record. This disc ID contains predetermined the number of disc identification bits (10), the detection means being they are also adapted to detect disk identification whose bits they are stored on the record carrier (1) diffusely. Equipment for the record on the record carrier (1) includes write means for inducing a detected change on the carrier layer (1) recording means, the recording means being further adapted for writing disc identification to the record carrier (1). This disc identification includes a predetermined number of bits (10) disc identification, wherein the write resources are also adapted to write disk identification bits on a carrier (1) record. The record carrier (1) contains identification a disc that contains a predetermined number of bits (10) identifying the disc stored on the record carrier (1) scattered.

Description

Technical field

The invention relates to a method of storing a disc identification on a record carrier comprising tracks in which information can be stored, the disc identification comprising a predetermined number of identification bits. The invention further relates to a record carrier reading apparatus comprising a system for detecting and reading information present on the record carrier, the system comprising detection means for detecting disc identification on the record carrier, the disc identification comprising a predetermined number of disc identification bits. The invention further relates to a record carrier recording apparatus comprising write means for causing a detectable change on the record carrier layer, the write means further adapted to write the disc identification to the record carriers, the disc identification comprising a predetermined number of bits of the disc identification. The invention also relates to a record carrier comprising a disc identification stored on the carrier, the disc identification comprising a predetermined number of bits of the disc identification.

BACKGROUND OF THE INVENTION

The method according to the invention can be used on various types of already known record carriers, such as CD-R, DVD + RW and MO disc. Since the literature uses a number of terms for disc-IDs as an identifier, disc identifier, disc code, identifier, it will be understood for clarity what is meant by the term disc-IDs in the description of the present invention. Disc-ID • •

It consists of information of a predetermined bit length stored on the record carrier, the purpose of which is to distinguish the record carrier from other record carriers of the same type.

It should be understood that the disc identification for the record carrier is comparable to fingerprints and can perform the same function as fingerprints. It is important that the presence of the disc identification ensures that the individual record carriers can be distinguished from each other and not just the type of record carrier (for example, CD-ROM, CD-R or CD-RW).

The method of the invention is not limited to circular record carriers but can also be used for non-circular record carriers such as tapes and cards.

Registering a unique disc identification on a record carrier is important for various reasons. European patent application EP 0 785 547 A2, hereinafter referred to as document D1, discloses as an advantage of recording a unique disc identification that a computer system using these record carriers can perform tracking according to a list of errors present on different record carriers. This system can easily detect when a record carrier is not working or should be replaced or copied. Registration of the identification on the record carrier may also be important in the cryptocommunication method. In this case, disc identification can be used to provide access to encrypted information on a record carrier along with keys (for example, what is referred to as shared secret) present on the recorder or player. The use of disc identification on the record carrier is also advisable in the area of •

This protection is greatly simplified when the individual record carriers can be distinguished from each other. To enable this goal, each record carrier receives a unique identification key. Using this identification (audio / video (A / V) data) associated with the recorder.

the disk drive identification code is data (for example, with a physical medium, i.e., the method of the type described in the introductory paragraph is known, inter alia, from D1), which describes a method for storing one disk identification (disc ID) If there is no disc-ID on the record carrier, a unique disc-ID is generated for this purpose and recorded in the reserved area of the record carrier If an MO disk is used, the unused sector in the defect can be used as the reserved area. management area (DMA) When a CD-R is used, a directory (TOC, table of contents) in the boot area can be used as a reserved area.

The disc identification as described in document D1 is recorded in the reserved area of the record carrier. Thus, disk identification is vulnerable to hacking attempts and removal of disk identification. Not only will it be easy to find the disc identification recorded in the reserved area on the record carrier, but it will also be easy to remove this disc identification, for example by providing the same binary value to all the bits constituting the disc identification. In addition, it will be easier to produce multiple disks that all have the same disk identification so that they cannot be distinguished from each other.

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SUMMARY OF THE INVENTION It is an object of the present invention to provide a fiction of a disc on record carriers to go and remove.

SUMMARY OF THE INVENTION

For this purpose, the method according to the invention is characterized in that the disc identification bits are dispersed on the record carrier.

The invention is based, inter alia, on the recognition that, when storing the disc identification bits on a record carrier, it will be more difficult to find the entire disc identification and possibly remove it. By storing bits on a record carrier in a scattered manner is meant that one disk identification is stored on the record carrier in multiple portions of a limited bit size. Rewriting such a limited bit size portion is not easy and rewriting a single bit is not well possible with conventional equipment (such as CD-R and CD-RW recorders). The minimum bit size that can be implemented in a single write operation is of the order of tens of bits, for example 32 bits. The ratio between this minimum bit size and the size of the entire disk identification is, for example, 20%. This corresponds to a 160-bit (5x32-bit) disk identification. By dispersing the different bits of the disc identification on the record carrier into groups that are smaller than this minimum bit size, it will be difficult to remove the disc identification. This has the advantage, inter alia, that if the disk identification forms part of a copy protection system or a cryptocommunication system, these systems will be more reliable and more difficult to hack.

reliable identities were difficult •

Another embodiment of the invention is characterized in that the disc identification bits are stored scattered on the record carrier in groups of one bit.

If the disc identification bits are stored scattered in groups of one bit on the record carrier, it will be difficult to find the entire disc identification and possibly remove it.

A further embodiment is characterized in that the disc identification bits are stored in positions reserved for storing non-data bits.

It is known that many bits, referred to as non-data bits, are not used to store data on many types of frequently used record carriers, but there are a number of other reasons for their presence. For example, in the description of the standard physical Audio-CD format (referred to as the Red Book), non-data bits are defined, inter alia, as error correction bits, merge bits, and sync bits. For details, refer to the standard Audio-CD format (see International Standard IEC 908).

It is also clear from the above that the data capacity of the record carrier is reduced if the disc identification is stored in a reserved area of the record carrier where the data is also to be stored. By using non-data bits to store the disc identification bits, a disc identification is created that does not reduce the total data capacity of the record carrier.

In addition, it should also be noted that the bits of the disc identification can also be stored in positions which, according to the description of the standard physical format of the respective record carrier, do not function. These positions are suitable because the value of the bits in these positions can be freely selected. This freedom provides the ability to store any desired disc identification on the record carrier.

Another embodiment is characterized in that the disc identification bits are stored in the preamble of the data bits on the record carrier.

By storing the disc identification in the preamble of the data bits on the record carrier, the disc identification is stored in a reserved area of the record carrier where only non-data bits are stored. This does not reduce the data capacity of the record carrier. For the description of the preamble of the data bits and its function, reference can be made to the description of the figures.

Another embodiment is characterized in that the disc identification bits associated with one disc identification are stored in a predetermined number of tracks.

The various tracks on the record carrier are numbered so that the information in the tracks can be traced again. By storing the disc identification bits associated with one disc identification in a predetermined number of tracks, it will be easier and faster to find and read the disc identification, since it will be easy to find the beginning of the disc identification with reference to the track number to be read.

Yet another embodiment of the invention is characterized in that:

the same number of bits of the disc identification are stored in the tracks.

The information is stored on different types of record carriers in so-called tracks. Typically, the track includes a portion including, but not limited to, a track address, followed by a portion in which information may be stored. The various tracks on the record carrier are numbered so that the information present in the tracks can be found. If the same number of disc identification bits are stored in each track, finding and reading the disc identification will be easier and faster. To store, for example, a 160-bit disc identification, twenty tracks are required to store the disc identification if eight bits of the disc identification are stored in each track.

Another embodiment is characterized in that the disc identification can be stored on the record carrier several times.

It will be appreciated that if the disc identification is present on the record carrier only once, damage to the record carrier at the point where it is recorded may result in the loss of that disc identification. This also applies to the case where the disc identification consists of disc identification bits that are dispersed on the record carrier. When the disc identification is no longer legible from the record carrier, the information that may be present on the record carrier in encrypted form is no longer accessible when the disc identification is used to provide access to this type of information. Recording multiple disc identifications whose bits are stored scattered on the record carrier reduces the risk that no readable disc identification remains on the record carrier.

Another embodiment is characterized in that the same number of tracks is used to store the disc identification.

Using the same number of tracks to store the disc identification will make finding and reading the disc identification bits easier and faster. Referring to the track numbers on the record carrier, it can then easily be determined which disc identification bits are present in which track.

Another embodiment is characterized in that the disc identification byte is formed by eight bits of the disc identification having the same position in a direction perpendicular to the reading direction of the record carrier.

Since the disc identification bits having the same position in the direction perpendicular to the reading direction of the record carrier form a disc identification byte, the error effect is reduced. In case of damage, errors fall into one byte. When a circular record carrier is used, the disc identification byte is made up of eight disc identification bits having the same tangential position. Since, in the case of error correction, this error correction is preferably performed at the byte level, the local damage having the magnitude of eight feet in the tangential position will result in one byte with eight errors. If the disk identification bytes are formed in a sequence in which the disk identification bits are read from the record carrier (i.e., in a sequence in which the record carrier data is also read), local damage having an eight track size in a tangential position will result in eight bytes, each with one error.

The device according to the invention is characterized in that

The means are also adapted to detect a disc identification whose bits are stored in a scattered manner on the record carrier.

Another device according to the invention is characterized in that the recording means are also adapted to write the disc identification bits to the record carrier in a scattered manner.

The record carrier according to the invention is characterized in that the disc identification bits are dispersed on the record carrier.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 shows a first embodiment of a record carrier with a disc identification according to the invention; FIG. 2 shows an enlarged detail of a part of FIG. 1; FIG. FIG. 4 shows a second embodiment of a record carrier with disc identification; and FIG. 5 is a block diagram of an apparatus for reading and writing a record carrier according to the invention.

DETAILED DESCRIPTION OF THE INVENTION

Fig. 1 shows a record carrier with a disc identification according to the invention, for example a recordable optical disc having a high recording density. The record carrier 1 has an annular aperture 2. This record carrier comprises a relief header 3, evenly divided into eight positions on the record carrier. These embossed headers are formed during manufacture of the record carrier. The record carrier 1 is divided into three areas with a large number of tracks 4. In this case, these areas are, for example, a lead-in area, a data area, and an output area. Footprints in the data stream * · · · ··· * ··

The -10-areas and exit areas have positive numbers, starting from track number 0, with track numbers rising toward the outside of the record carrier. Traces in the lead-in area have negative numbers, and the track numbers drop toward the record carrier's circular opening. The relief header 2 is followed by boot data.

Fig. 2 shows an enlargement of the area 5 of Fig. 1. FIELD contains the data zone 6, the embossed header 2 and the insertion zone 7. This embossed header ^e j 2 present between the data region 6 and the loading region 7. The data zone 6 is preceded by associated loading region 7 and an associated embossed header 3 ^, This combination is then repeated many times. In Figure 2, this combination is repeated twice.

The lead-in area 7 includes, inter alia, a preamble 8. The preamble in this embodiment is a preamble of data bits 6. The preamble 8 is present in the lead-in area 7 to provide synchronization when the optical tags on the record carrier 1 are read. In addition to the preamble 8, the lead-in area 7 includes, inter alia, address information. One bit in preamble 8 in this embodiment is defined as bit 10 of the disk identification. By writing one disc identification bit at predetermined positions (in this case, preamble position 8) when writing to the record carrier 1, it is possible to generate a disc identification that cannot be easily found and removed.

It should be noted that the run-out area can also be incorporated directly after the data areas. This run-out area is followed by an embossed heading 2 · · «« r r r r ** ** ** ** ** ** ** **

If, in this case, the disc identification bit is stored in each track 4 after each embossed header 3 in the lead-in region, eight disc identification bits can be stored in each track. Thus, twenty tracks are required to create a 160-bit disc identification. For example, the disc identification bits are stored in groups of a single disc identification bit at positions reserved for storing non-data bits.

In another embodiment, the disc identifications are formed by storing disc identification bits in groups of a small number of bits on the record carrier. In another embodiment, the disc identifications are formed by storing the disc identifying bits dedicated to storing data bits.

The storage of the disc identification bits is not limited to the lead-in region immediately following the relief header, but in principle any position on the record carrier can be defined for storing the disc identification bit according to the invention. It is also possible to store the disk identification bits for one or more disk identifications in both the lead-in area and the data area and output area, or to select from one or more of these areas. In addition, it is possible to store a number other than eight identification bits in each track, such as sixteen or thirty-two.

The present description has focused on the physical position in which the disk identification bit 10 can be stored. The disc identification bits 10 present on the record carrier 1 will then have to be read and collected to produce a usable complete disc identification. In this first embodiment, as described

Referring to Fig. 1a, the disc identification bytes are formed by interconnecting the eight disc identification bits 10 present in the track. 4. Together, the disk identification bytes form the complete (complete) disk identification. An embodiment of the complete disk identification (ID-information) will be described below with reference to Fig. 3.

Fig. 3 shows an embodiment of a complete disc identification. The complete disc identification in this embodiment consists of reading multiple tracks on the record carrier 1 and reading the eight bits 10 of the disc identification from each track. In this example, the complete disk identification includes an 8-bit flag field 11, a 128-bit identification 12, and a 32-bit L3 checksum. The track numbers in which the disc identification bits are stored are indicated above the complete disc identification. Complete disc identification starts at n track number and ends at n + 20 track. The complete disk identification contains a total of 168 bits and is thus stored in 21 tracks.

The 8-bit flag field 11 has the following function. By selecting a bit pattern that rarely occurs on record carrier 1 for the 8-bit flag field 11, this flag field acts as a starting point for a new complete disc identification. When the device reads this fixed bit pattern, it means that the beginning of a new complete disc identification has been found. Thus, by attaching a flag field to the beginning of a complete disc identification, it is easy to find the disc identifications present on the record carrier 1. By determining that the flag field can only appear in the tracks, where the start may be complete • ·

-13 disc identification, searching for the complete disc identification that is present on the disc can be even faster.

The 32-bit checksum 13 allows identification of errors that occur when different bits of the disk identification are read. Instead of a checksum, it is also possible to store an error correction code after identifying the disc, which can correct errors that occur when different bits of the disc identification are read. A combination of checksum and error correction code is also possible. Two other possible embodiments of complete disc identification will be described below.

In another embodiment, the complete disk identification includes 88-bit reserved data, in addition to an 8-bit flag field, a 128-bit disk identification, and a 32-bit checksum. This complete disk identification contains a total of 256 bits and can be stored in 32 tracks. 88-bit dedicated data can be used to exchange information between devices that can read and / or write to record carrier 1. Dedicated data can be used to replace the broken key if the disk identification forms part of the cryptocommunication system. In addition, the dedicated data can be used to turn on or off given functions (such as watermark detection) in the device. If this complete disc identification is stored several times on the record carrier, it is possible for the stored disc identification to be the same for each disc identification, while the reserved data is not the same. This provides the possibility that more information is stored in these reserved data.

In a further embodiment, it comprises a complete identification.

-14 disk 8-bit flag field, 128-bit disk identification and 16-bit checksum, 96-bit error protection code, and 16-bit dedicated disk identification data contains a total of 256 bits stored in 32 tracks.

This complete and can be so

From the above description, it will be appreciated that at least one complete disc identification must be present on the record carrier 1 to encrypt, for example, A / V information. For this purpose, the process according to the invention can be used as follows. If a record carrier 1 is inserted into the recorder / player without previously recorded data or in the meantime deleted data, it will be necessary to create a new disc identification to obtain an unwanted copy protection system. This disc identification may be generated, for example, by a random number generator, which is present, for example, in a recorder / player. The disc identification bits 10 are then stored in groups of one bit in the preamble 8 of the lead-in region. This is preferably done in the first tracks of the record carrier, counted from the circular aperture 2. If the record carrier and data are inserted into the recorder / player, the first complete disc identification that is present is read. When this complete disk identification has been successfully read, it will be stored in the registry.

Fig. 4 shows a second embodiment of a record carrier with disc identification. The record carrier 1 again has a circular opening 2 and a relief header 2. The disc identification bits, which are stored in the lead-in area 7, again together form a complete disc identification. The carrier 1 has a defect 15. This defect 15 may be, for example, a damaged part or contamination. This defect • ·

-1515 extends from track m designated as track 16 to track m + 7 designated as track 17. In this embodiment, the disc identification bytes are formed by the disc identification bits having the same tangential position. The arrow indicates the direction in which the disc identification bits having the same tangential position are joined to form the disc identification bytes. The disc identification bits constituting these disc identification bytes are therefore radially interleaved, thereby reducing error propagation.

This is clear from the following. The defect 15 comprises eight feet in the tangential direction (the size of the defect and the distance between track m and track m + 7 are strongly exaggerated in this Figure 4). In this case, since the disk identification bits having the same tangential position, the disk identification byte, the reading from track m to track m + 7 will result in eight bytes of disk identification, one byte of the disk identification having eight errors and seven bytes of the disk identification being without errors (assuming defect 15 is the only defect from trace m to trace m + 7). Thus, this defect 15 will result in only one byte with errors. When disk identification bytes are formed by combining eight disk identification bits in each track (as in the first embodiment), this will result in eight bytes having each error, namely bytes formed by reading track m, track m + 1, feet m + 2, feet m + 3, feet m + 4, feet m + 6 and feet m + 7. From the foregoing, it will be appreciated that error propagation is limited if the disk identification bytes are formed by disk identification bits having the same tangential position.

The spread of errors can also be limited by avoiding the

By writing the disc identification bits or disc identification bits, the disc identification bits are stored in memory, and then the disc identification bits are scattered on the record carrier in a predetermined manner.

Figure 5 shows a device for reading and / or writing a disc identification according to the invention onto a record carrier. The device is provided with drive means 26 for rotating the record carrier 1 and a read head 27 for reading tracks on the record carrier. The read head 27 comprises an optical system of a known type intended to produce a light spot 28 focused on the tracks of the record carrier by means of a light beam 29 guided by optical elements such as a collimating lens 39 for collimating the light beam and a lens 40 for focusing the light beam. This light beam 29 is generated by a radiation source 41, for example an infrared laser diode, having a wavelength of 650 nm and an optical power of 1 mW. The read head 27 further comprises an actuator for focusing the light beam 29 on the record carrier, and a tracking actuator 40 for fine positioning the light spot 28 in the radial direction at the center of the track. The track can be scanned by a laser beam, but also by changing the position of the lens 40.

Upon reflection by the record carrier, the light beam 29 is detected by a detector 42 of known type, for example a quadrant detector that generates detector signals 31 including a read signal, a tracking error signal, a focus error signal, a synchronization signal, and a lock-in signal. For example, a beam splitting cube 43, a polarizing beam splitting cube, a pellicle or a retarder can be used for this purpose.

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The device is provided with tracking means 32 connected to the read head 27 to receive a tracking error signal from the read head 27 and to control the tracking controller 30. During reading, the read signal is converted to the output information indicated by the arrow 33, for example, in a read means 34 comprising a channel decoder and an error corrector. The device is provided with an address detector 35 for retrieving addresses from the detector signals 31, and positionally positioning means 36 for coarse positioning the read head 27 in the radial track direction.

The device is also provided with detecting means 48 for receiving the detector signals 31 from the read head 27. The detector signals 31 are used by the detecting means 48 to synchronize the reading means 34. The detector signals 31 are used by the detecting means 48 to synchronize the reading means 34. When reading the disc identification , the detecting means 48 ensures that the detector signals 31 supplied to the reading means 34 are interpreted and recorded as signals associated with the disc identification bits 10. The recordings are then used to generate the described complete disc identification, for example with reference to Fig. 3.

The device is further provided with a system control unit 37 for receiving from the control computer system or from the user and for controlling the device via control lines 38, for example a system bus connected to the drive means 26, positioning means 36, address detector 35, tracking means 32 and reader. For this purpose, the system controller 37 includes a control circuit, such as a microprocessor 37, a program memory.

-18a control ports for performing the procedures described below. The system controller 37 may also be implemented as a state device in logic circuits.

In another embodiment, the device may include not only a reading means 34, but also a write means for providing optically readable marks on a record carrier of a writable type, thereby allowing the device to fulfill both the read and write functions. The read head 27 will then be replaced by the read / write head 27. In this case, the read / write head 27 will include the write means. The recording means will then be adapted to write the disc identification bits to the record carrier dispersedly. The detecting means 48 then ensures that the recording means records the disc identification bits at predetermined positions.

In another embodiment, the apparatus also includes control means 49 for controlling access to information on the record carrier. These control means 49 create a complete disc identification by means of signals from the reading means 34. This complete disc identification that is read can then be compared to the information present on the device and then an output signal 50 is generated, for example, providing access to the information present on the carrier. a record, an authority to record information on a record carrier, or an authority to copy information on a record carrier.

While the invention has been elucidated with reference to the embodiments described above, it will be appreciated that other embodiments may be used to achieve the same objective. For example, it is possible to change the number of bits of the disc identification in each track and join •

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-19 bits of disk identification in different ways to create a total disk identification, depending on which error correction method is used. It is also contemplated that the invention resides in each new feature and / or combinations thereof.

Claims (17)

PATENT CLAIMS A method of storing a disc identification on a record carrier (1) comprising tracks (4) in which information can be stored, the disc identification comprising a predetermined number of disc identification bits (10), characterized in that the identification bits (10) the discs are dispersed on the record carrier (1). Method according to claim 1, characterized in that the disc identification bits (10) are stored scattered on the record carrier (1) in groups of one bit. Method according to claim 1 or 2, characterized in that the disc identification bits (10) are stored in positions reserved for storing non-data bits. Method according to any one of claims 1 to 3, characterized in that the disc identification bits (10) are stored in the preamble (8) of the data bits (6) on the record carrier (1). Method according to any one of claims 1 to 4, characterized in that the disc identification bits (10) associated with one disc identification are stored in a predetermined number of tracks (4). Method according to any one of claims 1 to 5, characterized in that the same number of bits (10) of the disc identification (10) are stored in the tracks (4). Method according to any one of claims 1 to 5, characterized by: - 21, in that the disc identifications are stored on the record carrier (1) several times. Method according to claim 7, characterized in that the same number of tracks (4) is used to store the disc identifications. Method according to claim 5 or 6, characterized in that the disc identification byte is formed by eight disc identification bits (10) having the same position in a direction perpendicular to the reading direction of the record carrier (1). An apparatus for reading a record carrier (1), comprising a system (34, 48) for detecting and reading information present on the record carrier (1), the system comprising detection means for detecting disc identification on the record carrier (1), the disc identification (1) comprises a predetermined number of disc identification bits (10), characterized in that the detection means are also adapted to detect the disc identification, whose bits (10) are dispersed on the record carrier (1). An apparatus for recording on a record carrier (1), comprising writing means (27) for causing a detectable change on the layer of the record carrier (1), the writing means being further adapted to write a disc identification to the record carrier (1), said identification The disc comprises a predetermined number of disc identification bits (10), characterized in that the write means (27) are also adapted to write disc identification bits (10) to the record carrier dispersedly. • · -2212. Device according to claim 11, characterized in that the recording means (27) are also adapted to write the disc identification bits (10) on the record carrier (1) scattered in groups of one bit. Device according to claim 11, characterized in that the write means (27) are also adapted to write the disc identification bits (10) in positions reserved for storing non-data bits. Device according to claim 10 or 11, characterized in that the device also comprises means (49) for providing access to information on the record carrier. A record carrier comprising a disc identification stored on the carrier (1), the disc identification comprising a predetermined number of disc identification bits (10), characterized in that the disc identification bits are stored on the record carrier (1) scattered. Record carrier according to claim 15, characterized in that the disc identification bits (10) are dispersed in groups of one bit on the record carrier (1). The record carrier of claim 15, wherein the disc identification bits (10) are stored in positions reserved for storing non-data bits. The record carrier according to claim 15, characterized in that multiple disc identifications are stored on the record carrier (1).