RU2212062C2 - Record medium and record protection method - Google Patents

Abstract

FIELD: digital data recording on and reproducing from mirror disk. SUBSTANCE: writable and/or rewritable record medium includes initial domain, final domain, and user's data domain. Record medium saves write protection information capable of protecting data recorded on data medium against unwanted record superposition or erasing, write protection information being saved as backup information in plurality of initial domain locations. As an alternative, initial domain is provided in addition with disk identifying area. As one more alternative, write protection information is saved as backup information in plurality of initial domain locations, record medium being writable/reproducible record medium complying with multipurpose digital disk specifications. EFFECT: provision for protecting case-residing disk against unwanted records. 13 cl, 20 dwg, 2 tbl

Description

 The present invention relates to optical recording and / or reproduction for recording digital data on a disc and / or reproduction of data from it, and more particularly, a write protection method for protecting user-recorded data on a write-once or rewritable medium from unwanted recording or erasure, and recording media for storing information from write protection.

BACKGROUND
The ZMCD standard (writable multipurpose digital discs) and the OZMS standard (write-once and re-readable) are the standards for write-once discs, and the standard MZDPPD (multi-purpose digital random access memory disk) and the standard PZMCD (rewritable multi-purpose digital disc) are standards for rewritable disc.

 In accordance with the ICSDMP standard, published in July 1997 under the title “IDC Specifications for a rewritable disc, Part 1,“ Physical Specifications, Version 1.0, ”the MRCPD contains a cassette containing a disc, and discs from type 2 and type 3 cassettes can be used after removal from the cassette in the form of an open disk.

 The following three types of cassettes are defined for the MTDSDP drive. A Type 1 cartridge has a single-sided disc or double-sided disc, and the installed disc cannot be removed from the chassis. A single-sided disc is installed in the Type 2 cartridge, and the installed disc can be removed from the housing. However, when the disk is removed from the housing once, the opening of the sensing element capable of sensing the removal of the disk constantly changes to the open state so that the opening of the sensing element cannot be changed to the closed state again. Thus, it is possible to determine whether the disk was removed from the case or not. In a Type 3 cassette, the opening of the sensing element, also capable of determining whether the disk was removed from the case or not, opens at an early stage, so the disk can be removed from the case and installed in it without restriction.

 In addition, the cassette has a recording prohibition hole (alternatively called a “recognition switch for recording protection”), and in accordance with the standard on page PH-69, recording on a page is possible when the recording prohibition hole is closed and impossible when the recording prohibition hole open. That is, when the user intends to protect the data recorded by him from unwanted recording overwriting or erasing, the corresponding recording prohibition hole in the closed state changes to the open state, so that the recording device cannot record onto the disc of the corresponding cartridge.

 However, in a case using a Type 2 or Type 3 cartridge, a frameless disk can be used without a case, as described above. This is because the disc can be used in a thin recording-reproducing device, for example in a compact portable computer, in which it is impossible to install a cassette. However, the above specifications do not define any write protection, other than a write protection hole attached to the cassette.

 For example, when a user, after removing a disc installed in a case that protects against writing, inserts the disc into a thin recording-reproducing device in which it is not possible to insert a cassette, the write protection by the write-protect hole is no longer valid.

 In addition, there are many specifications related to the IDC, for example, the specification of the MCDE (specification of the MCD for read-only memory), the specification of the MCD (specification of the MCD for a recordable disc). In addition, many specifications for rewritable MCDs that have not yet been defined can be taken into account, for example, the MCD specification for a rewritable and readable disc, which is very similar to the specification of the MCD and the specification of the MCD for a higher density disc. Such a series of specifications with the prefix WDC is called the “WDC family”.

 A computer-based system also contains various attributes, such as read-only and read-only protection, which can prevent arbitrary changes to recorded data using the attributes of the file on which the data is recorded. However, when disk management is performed at a lower level than that of the file system for managing the file, for example, when recording and playback are not directly performed through the file system, when the disk is initialized, where the entire file system is not referenced, or when the attributes of each file cannot be taken into account, this method is not a reliable way of protection. Therefore, a method of protecting data from an unallocated MDCPPD from unwanted overwriting or erasure is not yet widespread.

 In the case of the MDCPPD, the disk can be used in an unpacked condition, as well as in the case. However, in the case of a ZMCD or PZMCD, it is not possible to use a disk in a case, so the need to protect an open disk from unwanted recording or erasure increases. However, when using a case-free disk removed from the case, it is impossible to use the recording prohibition hole, therefore, write protection must be provided on the disk itself.

 The ZMCD specification, the 3.95GB specification (Version 1.0) and the 4.7GB specification (final plan, version 1.9) do not mention the write protection method for the open disk. Meanwhile, the specifications of PZMCD were prepared on the basis of the specification of ZMCD, and in particular. Version 1.9 defines the use of a housing without a case. However, if the additional specification defines the use of the disk in the case (for example, continued use), then the write protection method to the caseless disk will not be applicable here, since the usual write protection method is used, which is applied to the MDCPPD using the write inhibit hole.

 If the specification of the PZMTSD allows the use of a housing, then recording can be prevented by using the recording prohibition hole, as in the MCPDPD. However, if the user has forgotten to put the state of the write prohibition hole into the write prohibition position, then an unexpected erasure or overwriting of the data recording may occur.

SUMMARY OF THE INVENTION
An object of the present invention is to provide a recording medium on which write protection information is stored on a disc contained in a housing.

 Another objective of the present invention is to provide a recording medium on which write-protect information capable of protecting a housing disk from unwanted recording overwriting or erasure is stored on the disk when the housing disk is removed from the housing.

 Another objective of the present invention is to provide a write protection method for a recording and / or reproducing device capable of protecting information recorded on a recordable and / or rewritable medium from undesired recording overwriting or erasure.

 In order to achieve the first and second objectives of the present invention, there is provided a usable recordable or rewritable recording medium contained in a cassette body or in an open case in which the recording medium stores write protection information capable of protecting the recorded data on the recording medium from unwanted recording overwriting or erasure.

 In order to achieve the third objective of the present invention, there is provided a write protection method for an optical recording and / or reproducing apparatus on a disc on which data recorded on a recordable or reproducible recording medium including a start area, an end area and a user data area are protected from unwanted overwriting or erasure, the method comprising the steps of (a) checking the write protection information stored on the recording medium, and (c) prohibiting the recording of data on the recording medium in accordance with Twi with write protection information.

BRIEF DESCRIPTION OF THE DRAWINGS
The above objectives and advantages of the present invention will become clearer from the detailed description of its preferred embodiments with reference to the accompanying drawings, in which:
FIG. 1 is a perspective view of a cassette for an MPDCS (Multi-Purpose Digital Random Access Memory Disk) having a recording prohibition hole;
FIG. 2 illustrates the structure of a conventional MCPAP;
FIG. 3A and 3B illustrate the data structure of a defect management area (DMA) of a conventional MCPAP;
FIG. 4A and 4B illustrate examples of a data structure of an OAA of a CDCMPD disc for storing write protection information in accordance with the present invention;
FIGS. 5A and 5B illustrate further examples of a data structure of an OAA of a CDMPD disk for storing write protection information in accordance with the present invention;
FIG. 6 is a flowchart illustrating a write protection method according to a preferred embodiment of the present invention;
FIG. 7 is a flowchart illustrating a method for correcting write protection information in accordance with the present invention;
FIG. 8 illustrates the structure of a disc identification area for storing write-protect information in accordance with the present invention;
FIG. 9 illustrates the data structure of the write protection information stored in the disc identification area shown in FIG.
10 illustrates a disk structure satisfying the general specifications of ZMCD and PZMCD;
11 illustrates the structure shown in figure 10 of the initial area;
FIG. 12 illustrates the structure of the control data area shown in FIG. 11;
FIG. 13 illustrates the contents of the remote sensing (recording management data) field of the RAM (recording management area) in accordance with the specifications of ZMCD and PZMTSD;
FIG. 14 illustrates the contents of the conventional 0 field SAR shown in FIG. 13;
Fig. 15 illustrates the content 0 of the DLD field for storing write protection information in accordance with the present invention, and
FIG. 16 is a flowchart illustrating a write protection method according to another embodiment of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION
In FIG. Figure 1 shows a recording prohibition hole for a cassette that conforms to the ICSDMP specification. Note that reference numeral 1 indicates a recording prohibition hole, and reference numeral 2 indicates a sensor hole used to determine whether a disc has been removed from the case.

 In FIG. 1, the closed hole 1 of the recording ban indicates that recording is allowed, and the open hole 1 of the recording ban indicates that recording is prohibited.

 Thus, when the recording prohibit hole 1 is opened in the corresponding ICCDPD recording / reproducing device, data recording to the disc is prohibited even if a write command is input from the outside, so that information recorded on the disc can be protected from unwanted recording overwriting.

 Figure 2 shows the structure of a disk that meets the specification of the ICDMP. The disk consists of three parts, that is, the start area, the user data area, and the end area in the function aspect. In addition, the disc can be divided into a rewritable area and a non-rewritable area. In particular, the initial region comprises a read-only zone in the innermost part, which is a zone of unrecordable embossed relief data having recesses, and an area of rewritable data after the read-only zone, in which both recording and reproduction can be performed. Meanwhile, the final area and the user data area contain only the rewritable data area. The read-only zone of the initial area contains information about the physical characteristics of the disk. The rewritable data area of the initial region and the final region contains four defect management areas OUD1, OUD2, OUD3 and OUD4, in which information about disk defects is recorded, a disk test area for use by the manufacturer of the disk when checking the condition of the disk, and a drive test zone for testing recording and playback operations in the recording-reproducing device, the protective track area and the disc identification area.

 In version 1.0 of the MTsDPPD specification, the purpose of using the disk identification zone and its contents are not yet clearly described.

 On figa and 3B shows the data structure in the field of defect management (OAD), in particular described on page RN-155-RN-158 specifications MTSDPD, and especially they show the data structure of the sign of certification of data and sign of certification of the group, respectively, in the field of structure disk definition (SOD).

 All four defect management areas OUD1, OUD2, OUD3 and OUD4 are in the initial region and the final region, in which OUD1 and OUD2 are in the initial region, and OUD3 and OUD4 are in the final region, and identical information regarding disk defects is stored in each region and disk initialization. Recording such identical information in different areas, that is, in two areas of the OUD1 and OUD2 of the initial region and two regions of the OUD3 and OUD4 of the final region, is carried out to prevent the problem of unsuitability of data for use due to disk defects.

 As shown in FIG. 3A, in the 3rd byte position, that is, the BEP of the disc definition structure (SOD), there is a disc certification sign, and the disc certification sign contains “in progress” information showing the state of initialization of the disc, the sign of “user certification” indicating whether the disk is allowed by the user, and the “manufacturer’s certification of the disk” sign indicating whether the corresponding disk is allowed by the disk manufacturer, and the characteristic information recorded in the byte position of the PCB is information about the entire disk.

 In addition, at byte positions 16-39, i.e., BP16-BP39, each byte has a group certification attribute, as shown in FIG. 3B, in an identical configuration. Byte positions BP16-BP39 have initialization information of approximately 24 recorded areas, that is, a group defined in Version 1.0 of the ICSDMP specification. That is, each group certification attribute has “in progress” information indicating the initialization status of the corresponding group, and a “user certification” attribute indicating whether the user has allowed the disk. Here the group indicates the special recordable areas of the disc.

In FIG. 4A and 4B illustrate examples of data structures of a disc certification feature and a group certification feature of a disc definition structure (SOD) area of a defect management (DMA) area in which write protection information in accordance with the present invention is recorded. In the data structure shown in FIG. 4A of the disc certification attribute, the “write protection of the disc” information is stored in binary bits B4 and B3 of the backup backup certification tag of the disc, in contrast to the data structure of the disc certification attribute shown in FIG. 3A, and is defined as follows:
Disc write protection
B4, B3 = 00B - The disc is not write protected.

 10c - The disc is write protected.

 Recording will not be performed on the entire disc, with the exception of the drive test area and the OUD area.

 11c - The disc is write protected. - It will not record on the entire disc. - These binary digits will not change to other values.

 Others are Reserve.

In the same manner, the data structure of the group certification attribute shown in FIG. 4B stores the “write protection of the group” information in binary bits B4 and B3 of the backup certification attribute of the “Backup” group, in contrast to the data structure of the group certification attribute, shown in FIG. 3B, and is defined as follows:
Group write protection
B4, B3 = 00B - The group is not write protected.

 10c - The group is write protected. User data will not be written to this block.

 Others are Reserve.

 In the table. 1 shows the status of the binary digits B4 and B3 of the sign of certification of the disk and the status of the binary digits of 4 and B3 of the sign of certification of the group.

 In the table. 1, flexible write protection means that write protection can be released (unlocked), that is, the write protection state can be changed to a rewritable state by setting the corresponding binary bit B4 to "0". Hard write protection also means that write protection applies to the end area as well as the start area, so that the write protection state cannot be restored to a rewritable state.

 With hard write protection for a group that makes part of the hard disk write-protected, it does not provide advantages for the user in use, but not in the technical aspect, and in particular there is a processing problem in the corresponding group when the entire disk is re-initiated. Thus, it is disadvantageous to set hard write protection for the group.

 As shown in the data structure of FIGS. 4A and 4B, the disc write protection information is recorded in the disc definition structure (SOD) of the defect management area (ODD), and the identical “write protection” information is recorded four times on the same disc, so that the reliability of the write protection information is increased on the disk.

 When a write-protected casing is inserted for use in a case whose write-protect hole is in a rewritable state, or if a casing that is not write-protect is inserted in a case whose write-protect hole is in a write-protected state stored on the disc information prohibition of recording cannot correspond to the state of the holes of the prohibition of recording the case.

 In this case, if either the disk or the case is write protected, they prefer such work that it is suitable for the write protection state. This is because, in the position of the user, it is preferable that the content of the data in this case is also checked without overwriting, and not for damage to important data due to overwriting.

 FIGS. 5A and 5B show further examples of data structures of a disc certification feature and a group certification feature, respectively, of a disc definition structure (SOD) area of a defect management (DMA) area that stores write protection information in accordance with the present invention.

In the case where the write protection information is in the disc certification attribute shown in FIG. 5A, only one binary bit B4 can be used, regardless of whether the write protection information is intended for hard write protection or for flexible write protection, which is defined as follows:
Disc write protection
v4 = 0v - The disc is not write protected.

 1c - You cannot write to the entire disc, except for the drive test area and the OUD area.

As shown in FIG. 5B, a group test flag may store write protection information using only one binary bit B4, which is defined as follows:
Group write protection
c4 = 0c - The group is not write protected.

 1c - The group is protected from writing. User data will not be written to this block.

 In this case, it is preferable to use the binary bit B4 of the sign of certification of the disk and the binary bit B4 of the sign of certification of the group. However, instead of using the B4 bit, a disk certification flag or a group certification flag, any “Backup” binary bit can be used.

 In addition, you can not use the binary bit v4 sign of the certification of the group, that is, the sign of "write protection of the group." This is effective in a drive in which only a special group is not write-protected, in which case the binary bit B4 of the group certification attribute is “Backup”, as in conventional certifications.

 The present invention can be applied to a case without a recording prohibition hole, and information on a disk can be effectively protected in this case using write-protected information stored on the disk.

 6 is a flowchart illustrating a write protection method according to a preferred embodiment of the present invention. First, it is checked whether the disk is installed in the case (step S101), and if the disk is installed in the case, the condition of the write-off hole of the case is checked (step S102). That is, when the prohibition hole is closed, this means that the cassette is not write-protected. When the recording prohibition hole is open, it means the cassette is write-protected.

 If it is determined in step S101 that the disc is not installed in the case, or after checking in step S102 the state of the write inhibit hole, the sign of write protection of the disc is checked (step S103). That is, the signs of write protection are checked in the sign of disk certification and the sign of group certification.

 In step S104, it is determined whether the write protection information is consistent with the state of the recording ban recording hole. That is, when the write protection information is recorded on the disc and the case of the write prohibition hole of the case is open, it is determined whether the write protection flag of the disc certification mark is set to the “write protection” state (step S105). Otherwise, the user is informed that the write-protect information of the disc is not consistent with the state of the write-enable hole of the case (step S106).

 If the write protection flag of the disk certification attribute is set in step S105 as a write protection state, or if either the disk or the case shows the write protection status, even if both write protection states of the disk and the case are not consistent at step S106, check (step S107) whether the disc is set to the "hard write protection" state. If the disk is set to the "hard write protection" state, it is prohibited (step S108) to write data on the entire disk, including the start area and the end area, but not the user data area. Otherwise, it is forbidden (step S109) to write data in the user data area, and not in the drive test area and the defect management (OA) area.

 If it is determined in step S105 that the write-protect flag of the disc certification mark is not set to the "write protection" state, then it is checked whether the write-protect flag of the group certification mark is set to the "write-protect" state (step S110). If the group certification attribute is set to the "write protection" state, then data recording in the corresponding group is prohibited (step S111). Otherwise, data recording is allowed in the rewritable area (step S112).

 Shown in FIG. 6, the write protection method corresponds to the case of using the disc certification feature containing the hard write protection feature shown in FIG. 4A and the group certification feature shown in FIG. 4B. When the disc certification attribute shown in FIG. 5A and the group certification attribute shown in FIG. 5B are used, the steps S107 and S108 shown in FIG. 6 are not performed. When, in step S105, the disc certification flag is set to the "write protection" state, data recording in the user data area in step S109 is prohibited.

 FIG. 7 is a flowchart illustrating a method of setting a rewritable disc in a write-protect state, or changing a write-protect state of a disc to a rewritable state. A method for correcting write protection information will now be described with reference to the program flowchart shown in FIG.

 As shown in FIG. 7, when a disc or cartridge is inserted in the recording / reproducing apparatus, the write protection information is checked (step S201). Then, it is determined (step S202) whether the user has entered the write protection information, and after the user has entered the write protection information, it is determined (step S203) whether the user has set the write protection information. If the user-set information is write-protect information, then the corresponding write-protect flag of the disc is set to the write-protect state (step S204).

 If the information set by the user in step S203 is not the write protection information, then it is determined (step S205) whether the information set by the user is the write protection release information. If the user-set information is write-protection release information, then it is determined (step S206) whether the current disk is in the hard-write-protect state. If the current disk is in hard write protection, the user is informed (step S207) that the write protection cannot be released. If it is determined in step S206 that the disc is not in a state of hard write protection, then the corresponding write-protect flag of the disc is set to the overwrite state (step S208).

 In addition, when completing the write protection setting or releasing the write protection of the disc, that is, when completing step S204, S207 or S208 and installing the disc in the case, it is determined in step S209 whether the condition of the write-protect hole of the case is consistent with the write-protect information, stored on disk. If the condition of the write-inhibit hole of the case is not consistent with the state of the disc, the user is informed of such a difference (step S210), and then the procedure is completed.

 The method for correcting write protection information shown in FIG. 7 can be performed by inserting an open disk or inserting a disk into the case, and can be performed after the write protection is controlled using the write protection information, as described with reference to FIG. 6.

 In a preferred embodiment of the present invention, disc write protection information is recorded in the disc defect management area. However, instead of the disc defect management area, the disc identification area shown in FIG. 2 can be used. A disc identification area is present in the start area and in the end area, like the disc defect management area. Thus, recording identical information two or more times in the disc identification zones located in the initial region and in the final region can guarantee reliability to the same extent as in the field of disk defect management.

 Since the disk identification zone is not currently used for a specific purpose, the advantage is that the disk identification zone does not contradict the information recorded in the disk defect management area. In particular, the information of the defect information area applies only to the MDCPTD, so it is difficult to maintain compatibility between discs for optical recording-reproduction. Meanwhile, since the disc identification area is not limited to a special disc, the disc identification area can be maintained consistent with another disc satisfying similar specifications.

 An example of storing write protection information using the disc identification area will be described with reference to FIGS. 8 and 9.

 As shown in FIG. 8, in the structure of the disk identification zone that stores the write protection information for the open disk, four signs for write protection are simultaneously recorded in the disk identification zone and two or more normal signs of the four signs are read. If the contents of the read indicia are consistent with each other, it is considered that the write protection of the disc is set.

 For example, four features are recorded only in the disc identification area of the start area, and disc identification information 1 of a block size (equal to 1 byte) is sequentially recorded four times in four blocks from the beginning of the disc identification area of the start area, and all first bytes of the disc identification information contain a security feature from the record. The identification information of the disk 1 block size is summarized, as shown in the table. 2.

The write protection (ST) attribute of the disc identification information corresponds to the most significant bit (BSS) of the first byte, as shown in FIG. 9. When the value of the feature (indicated by the "ЗЗ" symbol) is 1в (binary), this means that the entire area of the disc is write-protected, except for the disc identification area and the disc test area. In addition, when the value of the attribute is 0c, it means that the entire area of the disk is rewritable. That is, "ZZ" in Fig.9 is defined as follows:
ЗЗ = 1в The entire area of the disk is write-protected, with the exception of the drive test zone and the disk identification zone.

 = 0v The entire area of the disc is not prohibited for writing.

 The reason for reading only two normal signs from the four recorded signs of write protection is as follows. In the event that only one write protection feature is recorded, an error can be created in the area in which the corresponding feature is recorded, so that the area cannot be used. In addition, if only reading is allowed, and not writing, then there is the possibility of abnormal operation, so that information may not be permanently written to disk due to erroneous reading of the corresponding attribute.

 Meanwhile, when recording write protection information in a large number of locations, the problem is that the time required to read the corresponding information is increased. That is, the time required for a number of processes, from inserting a disk, including reading various information from the disk and recognizing the information required to control the disk by the microprocessor, can increase.

 However, in the case of correcting the write protection information, only the correction operation is performed. That is, due to the fact that information is not read, the recording time in units of several hundred milliseconds should hardly be taken into account. Thus, recording in four places is performed due to the reliability of the information, and the possibility of correcting errors during reading is taken into account. That is, if two errors are not created, or usually the corrected signs are read, and two of them coincide with each other, then the state of the write protection of the disc is set without reading the remaining signs, thereby increasing the speed of work.

 The write protection method proposed above is not limited only to the MTsDPPD, but it can be applied to a disk that has technical data, physically the same as ZMTSD-PZMTSD disks, and similar to the specifications of the WDCs that will now be described.

 Figure 10 shows the structure of the disk corresponding to the general specifications of the disks ZMTSD and PZMTSD. The disk is roughly divided into two parts in terms of functionality, including area 3 (recording) information and information area. The 3-information area is divided into OKM (power calibration area) for power calibration and RAM (recording management area), showing general information regarding the recording, that is, information about the disc recording mode, recording status, optimal power control and framing area, and the area information is divided into the initial region, the region of recorded data, in which the user can record data, and the final region, which is not yet defined in the specifications ZMCD and PZMCD.

 As shown in FIG. 11, the initial region contains an initial zone (content: 00h) for which a specific purpose is not defined, a reference code zone (channel binary code ZT-6T-7T) used to control the correlator of the radio frequency signal in the drive, the first and second buffer zones (contents : 00h) and a control data area including the contents shown in FIG.

 12, information about the physical format of the control data zone represents information about types and versions of specifications, disk size, maximum transfer rate, disk structure (one-sided / two-way), recording density and distribution of the data area, and disk manufacturing information is not associated with compatibility .

 On Fig shows the contents of the field of remote sensing (data management record) area management records (RAM), corresponding to the specifications ZMTSD and PZMTSD. The SCL contains the initial area of the SCL, which includes the system reserve field (content: 00h) and the unique identification field and the SCL field. As shown in Fig. 13, one field of remote sensing consists of 16 sectors, in which the first sector is assigned as the area of communication loss, ordinary disk information is stored in 0 field of remote sensing, information related to optimal power control (UOM) is stored in 1 field DUZ, special user data (content: 00h) are stored in the 2 DUZ field, and information about the border zone is stored in the 3 DUZ field. In addition, in the case of an ZMDC disk that meets the specifications of version 1.9, whenever 3–12 fields of the remote sensing are recorded, information from the 3-zone (recording zone), which includes recording elements, is stored, and 13–14 of the remote sensing fields are reserved.

 In the case of a rewritable or erasable disc, PZMTSD, the specifications of which are not yet defined, 3-zone information. stored in the 4th field of remote sensing, and the 5th field of remote sensing and the 12th field of remote sensing are assigned for storing information related to the management and certification of defects, taking into account the reliability used, certification before using the disk and defect management. The 13th DLM field and the 14th DLM field are also reserved.

On Fig shows the contents of the usual information of the disk stored in the 0 field DLD of Fig. 13. In Fig. 14, the byte positions of the BPO and BP1 store information about the DPS format (recorded only from 0001h), the byte position of the BP2 stores information about the state of the disk, and the byte position of the BPZ is reserved. Byte positions BP4-BP21 store information about the unique identifier of the disk, which stores the date and time of data recording in the form of a code AZSP (American standard code for the exchange of information). In the byte positions BP22-BP85, the information of preliminary excavations is copied, and the remaining byte positions BP86-BP2047 are reserved. Here, on the ZMCD disk, information about the state of the disk stored in the byte position of BP2 is determined as follows:
(BP2) - The status of the disk.

 00v - Indicates that the disk is empty.

 01c - Indicates that the disc is in instant recording mode.

 02c - Indicates that the disc is in incremental recording mode.

 03c - Indicates that the disc is finished when incremental recording is used.

 Others are Reserve.

 On Fig presents an example of a table showing the state when the write protection information is stored on a disk containing the specifications of disks ZMCD and PZMCD, corresponding to the present invention, using the usual disk information stored in 0 field DLD of Fig.13.

 That is, by determining the subsequent use of the backup byte position BPZ 0 of the DLD field, information can be transmitted to the drive that the current disk is write protected.

 (BPZ) - A sign of write protection of the disc.

 00c - Indicates that the disc is not write protected.

 01c - Indicates that the disk is write protected (hard).

 02c - Indicates that the disk is write-protected (flexible). Recording will not be performed on the entire disc, with the exception of OKM and so on.

 In the recording protection information of the present invention, 00c indicates that the disc is not write-protected, 01c indicates that the entire disc is write-protected (hard write protection), and 02c indicates that the entire disc except for a portion of the disc (e.g., OKM ), write protected (flexible write protection). In the present embodiment, the write protection information indicates that the entire disc is write protected or not write protected. However, information associated with the previous data is recorded in the DLD field of FIG. 13 whenever new data is recorded, so that write protection can only be set for recorded data corresponding to the DLD.

 For example, even if the write protection information is stored in the byte position of the BPS 0 of the remote sensing field, in addition to the remote sensing area, it is possible to record the write protection information on the open disk using the start region and the end region shown in Fig. 10. In addition, the byte position of BP2 O of the DLD field stores information about the state of the disc, so that write protection information can be stored in the byte position of BP2 of the DLD.

 Since the write protection information cannot be adjusted in the ZMDC after recording, given the consistency with the IDC disk family, the write protection information can be displayed through finalization, which means recording on a specific start area and end area. That is, the fact that the finalization is being completed indicates that the ZMCD is write-protected. Otherwise, this means that there is no write protection.

 In addition, since in the field of defect management OUD1, OUDZ and OUD4 of the disc of the MTsDPPD, the same content is recorded many times in order to eliminate errors, this guarantees reliability. In ZMTsD and PZMTsD such reliability is guaranteed by grouping the data of remote sensing data in the area of RAM and providing the data of remote sensing belonging to the same group with the same content.

The disk must include format information whenever the current disk is ZMCD or PZMCD, so that the ZMCD and PZMCD are compatible in the same drive. As shown in Fig. 15, the format of remote sensing can be determined using the byte positions of the BPO and BP1 field of remote sensing as follows:
(BPO, 1) - DUZ format
0001h - For Recording
0002h - To overwrite
0003h - For recording and dubbing compatible mode
FIG. 16 is a graphical diagram of a program illustrating a write protection method in accordance with another embodiment of the present invention, given the spread of application to the MCHP contained in the housing.

 First, it is determined (step S301) whether the disk is installed in the case. If the disk is installed in the case, then check (step S302) the condition of the write-off hole of the case. That is, if the case of the recording prohibition hole is closed, this means that the cassette is not write-protected, and if the recording prohibition hole is open, this means that the cassette is write-protected.

 If the disc in step S301 is not installed in the case, or when the state of the write inhibit hole is checked in step S302, the sign of write protection of the disc is checked (step S303). That is, they check the sign of write protection in the 0 field of remote sensing.

 Then, it is determined whether the write protection information corresponds to the state of the case of the write ban of the case (step S304). That is, when the write protection information is recorded on the disc and the write banning hole of the case is open, it is determined (step S305) whether the write protection flag is in the “write protect” state. Otherwise, the user is informed that the write-protect information of the disc does not correspond to the state of the write-protect hole of the case (step S306).

 If, in step S305 or after step S306, the write-protect flag of the disc is set to the "write-protect" state, i.e. if either the disk or the case is in a "write protection" state, even if the write protection information of the disk is not consistent with the state of the write-ban hole of the case, it is determined (step S307) whether the disk is set to the "hard write protection" state. If the disk is in the “hard write protection” state, then the entire disk, including the user data area, is write protected (step S308). Otherwise, only the user data area is protected from writing (step S309). In addition, if in step S305 the write-protect flag is not in the “write-protect” state, the disc is not write-protected (step S310).

 On a recordable and / or rewritable medium corresponding to the present invention, for example, on a disk that meets the specifications of the IDC, for example, the IDLDP, ZMZD and PZMZD, the data of an open disk that is not contained in the case can be effectively protected. In addition, when either the case or the disk is in write protection, data recording is prohibited and the user is given the opportunity to check the status of the disk or cartridge. As a result, data recorded on a disc can be effectively protected from unwanted overwriting or erasure.

Claims (13)

 1. Recordable and / or rewritable recording medium for recording data, including a start area, an end area and a user data area, characterized in that the recording medium stores write-protect information capable of protecting data recorded on the recording medium from undesirable overlay recording or erasing, wherein the write protection information is stored in reserve at a plurality of locations of the initial area.  2. Recordable and / or rewritable recording medium according to claim 1, characterized in that the recording medium is a frameless disc that is not contained in the cassette.  3. The recording medium according to claim 1, characterized in that the write protection information is stored in reserve four times.  4. The recording medium according to claim 3, characterized in that the four write-protect information stored in the reserve are stored in four separate blocks.  5. The recording medium according to claim 1, characterized in that the length of the write protection information is at least one byte.  6. Recordable and / or rewritable recording medium for recording data, including a start area, an end area and a user data area, characterized in that the recording medium stores write-protect information capable of protecting data recorded on the recording medium from unwanted overlay recording or erasing, wherein the initial area has a disc identification area, and the write protection information is stored in reserve at a plurality of locations of the initial area.  7. The recording medium according to claim 6, characterized in that the write protection information is stored in four locations of the disk identification area.  8. The recording medium according to claim 7, characterized in that when the write protection information read from one of the four locations of the disk identification area corresponds to the write protection information read from another of four locations of the same disk identification area, the disk set to write protection.  9. The recording medium according to claim 6, characterized in that the recording medium is a frameless disc not contained in the cassette body.  10. The recording medium according to claim 6, characterized in that the length of the write protection information is at least one byte.  11. The recording medium according to claim 7, characterized in that each of the four locations is a separate block.  12. Recordable and / or rewritable recording medium including a start region, an end region and a user data region, characterized in that the recording medium stores write-protect information capable of protecting data recorded on the recording medium from unwanted recording overwriting or erasure and the write protection information is stored in a reserve in a plurality of locations of the initial region, the recording medium being a recordable / reproducible recording medium satisfying multi-purpose specifications of the digital disc (IDC).  13. The recording medium according to claim 12, characterized in that the recording medium is a frameless disc that is not contained in the cassette. Priorities for items:
06/15/1998 PP 1-3, 5-7, 9-10 and 12-13;
06.24.1998 PP 4, 8 and 11.

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