JP3783928B2 - Optical information recording medium - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
In the present invention, information is sequentially added using a packet writing recording method (hereinafter referred to as “PW method”) of a write-once compact disc (hereinafter referred to as “CD-R”), and the additional writeable area remains. Even in the midway state, it has a structure in which all additional information from the first recorded packet to the last recorded packet can be read by a CD-ROM drive for reproducing a reproduction-only compact disc (hereinafter referred to as “CD-ROM”). The present invention relates to an optical information recording medium.
[0002]
[Prior art]
CD-R, which is a write-once recording medium, has been spreading in recent years because the recorded disc can be handled in the same way as a CD-ROM, and the recorded data cannot be falsified once in the recorded area.
[0003]
There are four types of CD-R recording methods: DAO (Disc At Once), SAO (Session At Once), TAO (Track At Once), and PW (Packet Writing).
[0004]
8 shows a DAO recording format, FIG. 9 shows a SAO recording format, FIG. 10 shows a TAO recording format, and FIG. 11 shows a PW recording format. FIG. 12 is a diagram showing a packet recording format used in the PW system, FIG. 13 is a diagram for explaining a state in the middle of additional recording before the finalizing process of the PW system, and FIG. 14 is a diagram in FIG. It is a figure for demonstrating that additional recording information cannot be read by CD-ROM drive from CD-R of the additional recording middle state shown. In each figure, common numbers and names indicate known basic components in the CD-R format.
[0005]
The DAO (disc at once) system is the most basic recording system for CD-R, as shown in FIG. 8, and is a recording format for a read-only CD disc (CD-DA, CD-ROM). The recording format is almost the same as that of the recording format.
[0006]
The CD-R is composed of an area A peculiar to the CD-R and an area B common to the read-only CD disc.
The area A is composed of (1) PCA (power calibration area) area and (2) PMA (program memory area) area.
(1) The PCA area is an area for determining the optimum recording laser power of the CD-R. (2) The PMA area is a data recording area for additionally writing temporary read-in information before main writing of the read-in information to the (3) lead-in area.
(3) In the DAO / SAO method in which the lead-in area and the (5) lead-out area are recorded simultaneously with the (4) program area, (2) even if temporary lead-in information is not recorded in the PMA area. good. Hereinafter, since the area A has no direct relationship with the present invention, detailed description thereof is omitted.
[0007]
The above-mentioned area B is composed of (3) lead-in area, (4) program area, and (5) lead-out area, and is called a normal session.
(3) The lead-in area is an area for recording start times of (3) program area and (4) lead-out area, (4) types of data to be recorded in the program area, and the like. (4) The program area is usually composed of a plurality of tracks, and user information to be recorded is recorded in each track. (5) In the lead-out area, (4) information indicating the end of the program area is recorded.
[0008]
The DAO format area B has the same structure as the recording area of the read-only CD disc, so that a CD-R recorded by the DAO format can be read by a CD-ROM drive.
[0009]
The above-mentioned SAO (session at once) system is an extension of the above-mentioned DAO system. As shown in FIG. 9, (3) lead-in, (4) program area, and (5) read This is a recording method for repetitive recording in session units with a set of out-out areas.
[0010]
In the case shown in FIG. 9, the number of sessions is 2, which is indicated by region B ′.
The first session shown in FIG. 9 is composed of (3) lead-in area, (4) program area, and (5) lead-out area. -It is composed of a DIN area, a (4) program area, and a (5) lead-out area.
In the case of the SAO method, since recording is performed in session units, the recorded CD-R can be read only by a multi-session compatible CD-ROM drive and CD-R drive.
[0011]
The above-mentioned TAO (track at once) method pays attention to the fact that there are many areas that cannot be used as user data in the above-mentioned SAO method, and as a method of reducing this unnecessary area, each session is divided into tracks. However, it is a method that allows each to be added.
[0012]
Specifically, the TAO method requires a lead-out area and a lead-in area between sessions in order for the above-mentioned SAO system to record in session units, and in the case shown in FIG. (5) The lead-out area needs to be recorded for 90 seconds, and the (3) lead-in area needs to be recorded for 60 seconds. This is a method for reducing the area that cannot be used as user data. As a result, (4) there is a merit that more user information can be recorded in the program area.
[0013]
In this TAO method, generally, the number of sessions is one, the session is divided into a plurality of tracks, and additional recording is performed in units of tracks.
Specifically, in the TAO system, as shown in FIG. 10, the number of sessions is 1, the number of tracks is 3, and the tracks are from the top (4) -1 track # 1, (4) -2 track # 2, (4) -3 Track # 3. The additional recording is performed in track units in the order of track # 1, track # 2, and track # 3.
(4) -3 After the additional recording of track # 3 is completed, lead-in information and lead-out information are recorded in the (3) lead-in area and (5) lead-out area, which is called finalization processing. As a result of the finalizing process, the CD-R added by the TAO method can be read by the CD-ROM drive.
[0014]
As shown in FIG. 11, the PW system described above is a system in which recording is performed in a more finely divided manner than the TAO system described above. (4) The number of tracks in the program area is 1, and the track is called a packet. This is a method of recording by dividing into units. Since information can be additionally recorded in a small unit called a packet, a large number of files can be recorded on a CD-R as if a file is recorded on a floppy disk (FD). Although not described in detail here, (4) the number of tracks in the program area may be two or more.
[0015]
In the example of FIG. 11, (4) the program area consists of one (4) -1 track # 1, and this track # 1 has three packets ((4) -1-1 packet # 1,. 4) -1-2 packet # 2 and (4) -1-3 packet # 3).
[0016]
As shown in FIG. 12, each packet of this PW system has a structure in which a predetermined block is added before and after a user data block (for example, 32 blocks) to be recorded. ), Run-in blocks (4 blocks) are arranged, and after that run-out blocks (2 blocks) are arranged. Here, one block is 2 KB, which corresponds to the sector structure of the CD-ROM disc (that is, the data amount of one block = 1 recording capacity of one sector = 2 KB (2048 bytes)).
[0017]
The link block (1 block) at the beginning of the packet is a block for superimposing connection (overlapping connection) with the runout block of the preceding (immediately preceding) packet, and the subsequent run-in block (4 blocks) is: When data is read from the user data block after recording, it is used as a run-up period for this reading. The run-out block (2 blocks) is a user data block protection area for seamlessly connecting the link blocks of subsequent (immediately) packets without interruption.
[0018]
In this PW system, as shown in FIG. 11, after all three packets (packet # 1 to packet # 3) are recorded, (3) lead-in area and (5) lead-out are performed by finalizing processing. Lead-in information and lead-out information are recorded in each area. As a result, the CD-R additionally recorded by the PW method after the finalizing process can be read by the CD-ROM drive.
[0019]
By the way, FIG. 13 shows that, in the PW method shown in FIG. 11, two additional writings are completed before the finalizing process, but the last bucket is in an unrecorded state. That is, (4) -1-1 packet # 1 and (4) -1-2 packet # 2 are recorded before finalization processing, but (3) lead-in area and (4)- The 1-3 packet # 3 and the (5) lead-out area are all unrecorded. In such a state, the recording of (4) -1-3 packet # 3 and the finalizing process for recording the lead-in information and the lead-out information in the (3) lead-in area and (5) lead-out area are not performed. Needless to say, the added information of the CD-R before finalization recorded by the PW method cannot be read by the CD-ROM drive.
[0020]
[Problems to be solved by the invention]
As a disc readable by a general CD-ROM drive, it is necessary to be a CD-R recorded by a system having the configuration of the area B shown in FIG. In this case, the area A peculiar to the CD-R is an unnecessary area because the CD-ROM drive does not have a reading function.
[0021]
FIG. 14 illustrates the following [Problem 1] and [Problem 2], in which the added information cannot be read by the CD-ROM drive from the CD-R before finalization processing in the PW method shown in FIG. Is.
[0022]
[Problem 1]
Problem 1 is that the read-in information cannot be read, and the CD-ROM drive cannot start reading the added information from the CD-R.
That is, in the reading of the CD-ROM drive, the first reading operation records the outline of the disc information. (3) Data (TOC (table of contents)) which is one of the lead-in information in the lead-in area Information). However, in the CD-R before the finalizing process as shown in FIG. 13, the read-in information cannot be read from the read-in area. Therefore, the reading of the TOC information becomes defective, and as a result, the reading operation is stopped. It is to end up.
[0023]
[Problem 2]
Problem 2 is that when a light beam emitted from the optical pickup enters an unrecorded packet immediately after the last recorded packet that has been additionally recorded, a tracking servo signal and a CLV (constant linear velocity) servo signal are entered in the unrecorded packet. Since the information for generating the signal is not recorded, the CD-ROM drive cannot generate these servo signals. Therefore, each servo fails in the unrecorded packet, and the rotation of the CD-R runs out of control. It is to do.
That is, when a CD-R recorded by the PW method before finalization processing is reproduced by a CD-ROM drive, the last recorded packet (4) -1-2 packet # 2) cannot be specified, and the reading -Bo collapses.
[0024]
That is, it is possible to read additional information from a CD-R added by the PW method before finalization processing with a CD-R recorder, but not with a CD-ROM drive.
[0025]
Here, what happens in the CD-ROM drive and the CD-R recorder when reading the final recorded packet before finalization processing shown in FIG. 13 will be described.
The CD-R recorder has a function capable of obtaining tracking and CLV servo signals regardless of whether the disk area (area B, shown in FIG. 11) is recorded or not recorded. That is, even if the light beam emitted from the optical pickup enters the unrecorded area (4) 1-3 packet # 3 in area B, the ATIP (absolute time) of the continuous groove recorded in advance on the CD-R Since the tracking servo signal and the CLV servo signal are not interrupted by the (in-groove) signal, there is no failure in the reading sequence. For this reason, after confirming the recording signal of the last recorded packet, the next packet writing can be performed from there.
[0026]
On the other hand, in the CD-ROM drive, when reading of (4) -1-2 packet # 2 is completed, it is not possible to obtain information as to whether or not there is a recorded packet in the immediately following packet, and actually the optical pickup. Only when the light beam emitted from the light enters the unrecorded area (packet recordable area: (4) -1-3 packet # 3) and the tracking servo breaks down, it is determined that the area is an unrecorded area. It is.
[0027]
When the CD-ROM drive enters this unrecorded area, tracking and CLV servo fail, and in some cases, the personal computer that controls the CD-ROM drive may hang up.
[0028]
Therefore, the present invention has been made in view of the above-described problem, and information is sequentially added using the CD-R PW method, and even in a state where additional recording is still possible, the top recorded packet is recorded. It is an object of the present invention to provide an optical information recording medium having a data structure in which all additional recording information from the last recorded packet to the last recorded packet can be read by a CD-ROM drive.
[0029]
[Means for Solving the Problems]
In order to solve the above-described problems, the present invention provides an optical information recording medium having the following configurations (1) to (4).
(1) As shown in FIGS. 1 to 5 and FIG. 11, PCA (1) PCA area, PMA (2) PMA area, lead-in area (3) lead-in area, program area (4) Program area) and optical information recording capable of sequentially adding information in accordance with a CD-R packet writing recording system (PW system) in which a lead-out area (5) a lead-out area is sequentially arranged. A medium,
A first region (region A) in which the PCA and the PMA are disposed;
A second area (area B) in which the lead-in area, the program area, and the lead-out area are arranged;
The program area is composed of at least one track (track # 1),
The track (track # 1) is composed of at least one packet (packet # 1, packet # 2, packet # 3),
Each packet includes at least a user data block, an address block, and a dummy block,
In the lead-in area, at least information on the number of tracks, the start time of the track, and the lead-out start time is recorded in advance prior to all additional recordings,
At the end of this additional writing (at the time of the second additional writing), the additional writing end information (○ symbol) is recorded only in the address block in the last packet (packet # 2), and at the end of the previous additional writing (the first additional writing) ), The postscript end information (○ symbol) recorded in the address block in the packet (packet # 1) that became the last packet is made unreadable (× symbol)
At the start of the next appending (third appending), the packet having an address block from which appending end information can be read is determined as the final packet (packet # 2), and the packet immediately after the final packet (packet # 2) An optical information recording medium additionally recorded from (Packet # 3).
(2) The optical information recording medium according to claim 1,
The address block of the first packet has the same number of blocks as the number of packets that can be additionally written after the second packet. (3) The optical information recording medium according to claim 1 or claim 2,
At the end of this additional writing, the additional writing end information recorded in the address block corresponding to the last packet at the end of the previous additional writing is overwritten with a specific signal, thereby making it impossible to read the additional writing end information. An optical information recording medium.
(4) The optical information recording medium according to any one of claims 1 to 3,
The information recorded in the dummy block is
An optical information recording medium, characterized in that the information is information that enables the tracking servo operation on the reproducing apparatus side to be continued for a predetermined period after reading the address block in the final packet.
[0030]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, preferred embodiments (Examples 1 to 5) of embodiments of the present invention will be described in order with reference to FIGS. 1 to 7 and FIGS. 15 to 22.
FIG. 1 is a correspondence diagram of the first embodiment of the present invention, and a solution that enables an optical information recording medium in which additional recorded information cannot be read in the additional recording intermediate state shown in FIG. 14 to be read by a CD-ROM driver. FIG. 2 is a diagram illustrating a new packet recording format according to the first embodiment of the present invention, and FIG. 3 is a diagram in which packet # 1 is additionally recorded using the recording format of FIG. FIG. 4 is a diagram for explaining the recording state of the address block of packet # 1 at the time of one additional recording. FIG. 4 shows packet # 1, at the time of second additional recording in which packet # 2 is additionally recorded using the recording format of FIG. FIG. 5 is a diagram for explaining the recording state of each address block of packet # 2, and FIG. 5 shows packet # 1 to packet # 3 in the third additional recording in which packet # 3 is additionally recorded using the recording format of FIG. Record of each address block FIG. 6 is a diagram for explaining the state, FIG. 6 is a diagram corresponding to the second embodiment of the present invention, and is a diagram for explaining a recording format of a packet having an address block total in packet # 1, and FIG. FIG. 15 is a diagram for explaining the recording format of a packet that does not include an address block in all the packets # 2 to # 101 except the packet # 1, and FIG. 15 and FIG. FIG. 17 is a correspondence diagram of Embodiment 3 of the present invention, and is a diagram for explaining the data structure of an address block before and after overwriting, and FIGS. 17, 18 and 19 are respectively diagrams of Embodiment 4 of the present invention. FIG. 20, FIG. 21, FIG. 22 are diagrams for explaining the data structures (1) to (3) of the new recording format, and FIG. 20, FIG. 21, and FIG. A corresponding view, and is a view for explaining a structural example of an optical information recording medium (1) to (3). The same components as those described above are denoted by the same reference numerals and description thereof is omitted.
[0031]
[Example 1]
As shown in FIG. 1, Example 1 of the present invention solves [Problem 1] and [Problem 2] shown in FIG. 14 with the following [Solution 1] and [Solution 2]. It is equipped with. That is,
[0032]
[Solution 1] is to record in advance lead-in information in the lead-in area {circle around (3)} before the start of additional writing using the PW method. On the other hand, (5) Readout information is recorded in advance in the leadout area as necessary.
[0033]
[Solution 2] is a packet recording format (FIG. 2) in order to prevent the light beam emitted from the optical pickup from entering the unrecorded area (4) 1-3 packet # 3. Is newly established.
For ease of explanation, FIG. 1 shows the same number of tracks and the same number of packets as in FIG. 13, but it goes without saying that the present invention is not limited to the number of tracks and the number of packets. .
[0034]
First, [Solution 1] will be described.
Here, (3) only the case where the lead-in information is recorded in the lead-in area will be described. (3) The lead-in information recorded in the lead-in area is the number of tracks, the track start time, the lead-out start time, the type of track (audio, data), and the like.
In the first embodiment shown in FIG. 1, the number of tracks is 1, and the type of track is data.
[0035]
Thus, as the lead-in information, it is not necessary to directly record the number of packets and the packet size, but the size of the program area recorded on one track is approximately the sum of the recorded packet sizes, and the lead-out information Start time is closely related.
Therefore, the lead-out start time can be set in advance from the total recording packet size or the maximum recording capacity of the recording medium.
[0036]
Thus, by using [Solution 1], lead-in information and lead-out information are recorded in advance in the lead-in area (3) and lead-out area (5), respectively, by the start of additional writing by the PW method. As described above, [Problem 1] can be cleared.
[0037]
Next, [Solution 2] will be described.
Solution 2 is a new bucket that makes it possible to determine the last recorded packet in order to prevent the light beam emitted from the optical pickup from entering the unrecorded area (4) 1-3 packet # 3. A new recording format (FIG. 2). As shown in FIG. 2, the new recording format of this packet includes link blocks, run-in blocks 1 to 4, user data block, address block, dummy block, and run-out block 1 from the beginning of each packet. , 2 are sequentially arranged. The new recording format of this packet is compatible with the sector format of CD-ROM.
[0038]
In the example of FIG. 2, the link block is 1 block, the run-in blocks 1 to 4 are a total of 4 blocks, the user data block is 32 blocks, the address block is 1 block, the dummy block is 10 blocks, the run-out block 1, 2 is 2 blocks.
[0039]
The recording format shown in FIG. 2 is obtained by inserting an address block and a dummy block between the user data block and the runout blocks 1 and 2 in the recording format shown in FIG. Are equal.
[0040]
This address block is used for determining whether or not the packet is the last recorded packet. The dummy block has the same role as the read-out information so that the light beam emitted from the optical pickup does not enter the unrecorded packet immediately after the packet when the packet is the last recorded packet. It has something.
[0041]
First, the function of this address block will be described.
At the time of the first appending in which user data is appended to the user data block of the first {circle over (4)}-1-1 packet # 1 (hereinafter referred to as “packet # 1”) using the packet recording format of FIG. As shown in FIG. 3, the sector on the medium side corresponding to the address block of the packet # 1 has a sector format of CD-ROM and indicates that there is a block without a read error in the CD-ROM drive. Record possible data (○) ”.
[0042]
In addition to “readable data (◯)”, information related to packet recording such as the number of packet recordings and the packet number can be recorded in this sector.
[0043]
The meaning of the “readable data (◯)” is shown as an example using “CD-ROM mode 1” which is a general CD-ROM sector format structure.
The format structure of “CD-ROM mode 1” includes a header area, a data area, and an error correction code area for each sector (for each address block).
[0044]
The header area is an area for recording information such as the address number of the sector. The data area is an area for recording 2048-byte user data. The error correction code area is an area for recording each data of EDC (Error Detection Code) and ECC (Error Correction Code). Using this EDC and ECC, error detection and error correction of user data recorded in the data area are performed.
[0045]
For example, “READ (10)”, which is a control command for a CD-ROM drive, is used to read user data from an address block (one block (= 1 sector), sector) recorded in the “CD-ROM mode 1” format structure. (With EDC / ECC correction) is used. As a result, when the user data is subjected to EDC / ECC error correction processing and is error data within the error correction capability, it can be read as the original correct value (original value data). As a result, the state in which all data (user data) in one sector can be read with an original correct value by error correction is “readable data (◯)”.
[0046]
Next, the address of packet # 1 at the time of the second additional recording in which user data is added to the user data block of (4) -1-2 packet # 2 (hereinafter referred to as "packet # 2") next to packet # 1. For example, an EFM signal, which is a signal for CD recording, is overwritten with a predetermined size with respect to “readable data (◯)” recorded in the medium side sector corresponding to the block. As a result of this overwriting, this “readable data (◯)” is different from the normal sector structure and cannot be read by the CD-ROM drive. It has “unreadable data (×)” indicating an error, that is, it is rewritten as recorded (FIG. 4).
[0047]
The meaning of the “unreadable data (×)” is the same as the “readable data (◯)”, but the “CD-ROM mode 1” that is a general CD-ROM sector format structure is used. An example is shown.
When an address block (one block (= 1 sector), sector) recorded with the “CD-ROM mode 1” format structure is overwritten to a predetermined size, each overwritten data in the sector is data of this predetermined size. As a result, the pit length (mark length) of each data changes (becomes longer than the original pit length (mark length)), and the value of the original pit length (mark length) And will be different.
[0048]
For example, “READ (10)” (with EDC / ECC correction), which is a control command of the CD-ROM drive, is used to read user data from the overwritten sector. As a result, user data different from the original pit length (mark length) is subjected to EDC / ECC error correction processing. However, if the error data exceeds the error correction capability, the original correct value (original Value data). As a result, the state in which all data (user data) in one sector cannot be read with an original correct value by error correction is “unreadable data (×)”.
[0049]
On the other hand, in the sector on the medium side corresponding to the address block of packet # 2, as shown in FIG. 4, the CD-ROM sector format (“CD -"ROM mode 1" format), "Readable data (o)" indicating that there is a block without a read error in the CD-ROM drive is recorded. In addition to “readable data (◯)”, information related to packet recording such as the number of packet recordings and the packet number can be recorded in this sector.
[0050]
As a result, the CD-ROM drive cannot read the “unreadable data (×)” recorded in the sector on the medium side corresponding to the address block of the packet # 1, but the packet # 2 immediately after this cannot be read. “Readable data (◯)” recorded in the sector on the medium side corresponding to the address block can be read.
[0051]
Therefore, the CD-ROM drive detects a change from “unreadable data (×)” to “readable data (◯)” from the sense data indicating the state of the CD-ROM drive, and packet # 2 is finally recorded. It can be determined that the packet is a completed packet.
[0052]
Further, at the time of the third additional recording in which user data is added to the user data block of (4) -1-2 packet # 3 (hereinafter referred to as “packet # 3”) next to packet # 2, the second additional recording described above. Similar to the “readable data (O)” recorded in the medium side sector sometimes corresponding to the address block of packet # 1, the medium side sector corresponding to the address block of packet # 2 For example, an EFM signal, which is a signal for CD recording, is overwritten with a predetermined size with respect to the “readable data (◯)” recorded in FIG.
[0053]
As a result of this overwriting, this “readable data (◯)” is different from the normal sector structure, and this cannot be read by the CD-ROM drive. It is rewritten as “unreadable data (×)” indicating that there is a block with − (FIG. 5).
[0054]
In contrast, the sector on the medium side corresponding to the address block of packet # 3 has a CD-ROM sector format ("CD-ROM mode 1" format) and a CD-ROM drive as shown in FIG. “Readable data (◯)” indicating that there is a block having no read error is recorded. In addition to “readable data (◯)”, information related to packet recording such as the number of packet recordings and the packet number can be recorded in this sector.
[0055]
As a result, the CD-ROM drive cannot read the “unreadable data (×)” recorded in the sector on the medium side corresponding to the address block of the packet # 2, but in the packet # 3 immediately after this “Readable data (◯)” recorded in the sector on the medium side corresponding to the address block can be read. Therefore, the CD-ROM drive can detect a change from “unreadable data (×)” to “readable data (◯)” and determine that packet # 3 is the last recorded packet.
[0056]
Thus, the CD-ROM drive sequentially reads the data recorded in the medium-side sector corresponding to each address block of packet # 1 to packet # 3 from head packet # 1 to packet # 3. When the data changes from “unreadable data (×)” to “readable data (◯)”, the packet corresponding to the readable data (◯) can be determined as the last recorded packet. .
[0057]
By the way, as described above, the CD-ROM drive reads the data recorded in the sector on the medium side corresponding to each address block of the packet # 1 to packet # 3, whereby the last recorded packet is recorded. However, in an actual CD-ROM drive, it has been found that this method may be inconvenient for the following reason. That is, the light beam emitted from the optical pickup of the CD-ROM drive needs to keep locking the medium tracking servo and CLV servo for a while after reading various data in the final recorded packet. Therefore, it has been found that it is necessary to read the EFM signal about one round of the medium.
[0058]
For this reason, in the packet recording format (FIG. 2) according to the first embodiment of the present invention described above, a 10-block dummy block that allows the EFM signal to be read about one round of the medium is inserted after the address block. However, since the CD-ROM drive can generate the tracking servo signal and the CLV servo signal based on the EFM signal read from the dummy block, the CD-ROM drive can read the last recorded packet. It was confirmed that the servo did not fail even after completing the above.
[0059]
[Example 2]
FIG. 6 shows the recording format of the first packet # 1 in the second embodiment, and this recording format is one block in the size of the address block except for the user data block in the first embodiment of the present invention in FIG. Is expanded to 100 blocks, which is called an address block total, and the number of blocks is equal to the number of recordable packets.
[0060]
FIG. 7 shows a recording format common to packet # 2 to packet # 101 of the second embodiment, which is equivalent to a user data block provided in place of the address block total of FIG.
[0061]
As shown in FIG. 6, the second embodiment of the present invention is a recording format in which the address blocks provided for each packet described in the first embodiment are all concentrated on the first packet # 1. The purpose is to speed up data access. In the case of FIG. 6, all address blocks (100 blocks) of packet # 2 to packet # 101 are concentrated on the first packet # 1, and an address block total (100 blocks) is formed here.
[0062]
In the second embodiment, overwriting to each address block constituting the total address block of the first packet # 1 is the same as the method described in the first embodiment. For this reason, packet # 2 to packet # 101 do not include individual address blocks as shown in FIG.
[0063]
Each address block forming the above-described address block total is recorded in a state of “readable data (◯)” when packet # 1 is recorded.
At the time of recording packets after packet # 2, the address block of each packet is overwritten with a predetermined size EFM signal or the like in the same manner as in the first embodiment, resulting in a state of "unreadable data (x)".
[0064]
Therefore, the CD-ROM drive detects a change from “unreadable data (×)” to “readable data (◯)”, and which of packet # 2 to packet # 101 is the last recorded packet. Is the same as in the first embodiment.
[0065]
As a result, even if all the address blocks of all packets # 2 to # 101 are not accessed as in the first embodiment, all packets # 2 can be obtained by listing only the total address blocks of one packet # 1. ˜ # 101 address block recording states (recorded packet, last recorded packet, unrecorded packet) can be recognized. As a result, compared to the first embodiment, it is possible to speed up access to all address blocks.
[0066]
In the example of FIG. 6, the address block total indicates that all address blocks up to 100 packets can be recorded. In addition, the fact that the address blocks # 2 to # 4 in FIG. 6 are “unreadable data (×)” means that packets # 2 to # 5 have been recorded, and the remaining packets # 6 to # 101 have not been recorded. Indicates a record.
[0067]
The second embodiment is characterized in the arrangement of the address blocks in the address block total. The head address block of the address block total is that of packet # 101, which is packet # 2 which is arranged in the following order (descending order) and the tail is added first.
[0068]
The reason for this is that in the CD-ROM drive, the “readable data (◯)” is read quickly, but the “readable data (×)” is read out, such as a data read retry of the CD-ROM drive. Therefore, it takes time, and this is because a difference of 10 times or more of the read time of “readable data (◯)” occurs.
[0069]
As in the packet recording format (FIG. 2) according to the first embodiment of the present invention, the number of recorded packets increases in the method of checking up to the packet # 100 in order (ascending order) from the first packet # 1. This is because it takes a long time to read “unreadable data (×)”, and it takes a very long time to confirm the final recorded packet after reading “readable data (◯)”. . However, with the method according to the second embodiment (in descending order), since the error-less packets up to the last recorded packet, the last recorded packet can be confirmed in a short time.
[0070]
[Example 3]
In the third embodiment of the present invention, the read time of the address block after overwriting described above (that is, the above-mentioned “unreadable data (×)”) is further shortened compared to the second embodiment, thereby speeding up the access. It is a technique to make it.
[0071]
In the second embodiment, the reason why it takes a long time to read the address block by overwriting is as follows.
(1) Error correction processing time depending on the size of the overwritten area
(2) Recognition method algorithm for “unreadable data (×)”
[0072]
Therefore, in Example 3, the following improvements were made to solve this problem.
(1) Reduction of overwritten area
▲ 2 ▼ Change in recognition method of “unreadable data (×)”
It is.
[0073]
[About reduction of overwritten area]
According to the verification by the “CD-ROM mode 1” format described in the second embodiment, even if the overwritten area in the sector is reduced to the minimum necessary level where error correction is impossible, it is about 1/3 of that before the reduction. It was found that “unreadable data (×)” can be recognized over time. That is, in order to put the sector (address block) in the “unreadable data (×)” state, it is not necessary to make all the data constituting each address block uncorrectable.
[0074]
Further, when performing scanning (reproduction scanning / additional scanning) for reading user data from the sector to be overwritten, an irradiation position deviation of the light beam emitted from the optical pickup may occur. When this occurs, the light beam is not irradiated into the sector (address block), but erroneously irradiated into other sectors adjacent to the sector. As a result, the user data of the sector cannot be read in order from the head data, so that the user data cannot be read accurately. As one solution to solve this inconvenience, the boundary portion in the sector that touches the boundary with the adjacent other sector is a space (blank) having a width capable of absorbing the irradiation position deviation of the light beam. It is to do. Thereby, even when the irradiation position deviation of the light beam occurs, the user data of the sector can be read in order from the head data.
[0075]
Here, the condition for overwriting the sector is limited to the minimum necessary number of data to be overwritten in accordance with the error correction capability of the sector format (“CD-ROM mode2 form2”) of the address block described later. As a result, the data read time can be shortened.
[0076]
[Change in recognition method of “unreadable data (x)”]
The CD-ROM format (“CD-ROM mode1” format structure) of the address block has been changed to (“CD-ROM mode2 form2” format structure). Further, the method of reading the address block after overwriting was also achieved by using “READ CD” as the sector data read control signal of the CD-ROM drive.
[0077]
The “CD-ROM mode2 form2” format uses only CIRC (Cross Interleaved Reed-Solomon Code) as a correction code without using the EDC / ECC used by the “CD-ROM mode1” format described above.
The format structure of “CD-ROM mode2 form2” includes a header area and a data area for each sector (for each address block). The header area and the data area are equal to the header area and the data area in the “CD-ROM mode 1” format.
In contrast to the “CD-ROM mode 1” format, the “CD-ROM mode 2 form 2” format can recognize uncorrectable (“unreadable data (×)”) with a small overwrite area, although its correction capability is reduced. Is.
[0078]
When the address block is recorded in advance in the “CD-ROM mode2 form2” format, overwritten with a predetermined size by the EFM signal, and read by the “READ CD”, all data in the address block is subjected to error correction by the CIRC. Thereafter, it is output from the CD-ROM drive in units of one sector.
[0079]
All data in the address block output in units of one sector from this CD-ROM drive is error-corrected by CIRC and returned to the correct value (original value) before overwriting, and overwriting exceeding the CIRC error correcting capability Due to the physical change of the recorded data due to, incorrect values that do not return to the correct values before overwriting are mixed.
[0080]
The second embodiment and the third embodiment are compared for reading the overwritten address block.
In the second embodiment, the sector format of the address block is “CD-ROM mode 1” format, and when this is read with READ (10) (with EDC / ECC), error correction capability is within the error correction capability of EDC / ECC. If it is, sector data is output from the CD-ROM drive, but if the error correction capability is exceeded, the sector data is not output and only an error message indicating that the sector cannot be read is output. And it took time to retry reading and repeat error correction before issuing this error message.
[0081]
On the other hand, in the third embodiment, the sector format of the address block is the “CD-ROM mode2 form2” format, and when this is read out with the READ CD (without EDC / ECC), the restored data within the correction capability is also obtained after the CIRC correction. Also, uncorrectable data exceeding the correction capability is also output. In this reading method, since there is no processing time for EDC / ECC correction, the time can be reduced by this processing time.
[0082]
The third embodiment utilizes the fact that the sector data of such an address block is correct or incorrect. FIG. 15 and FIG. 16 show the status of the recording data before and after the address block overwrite in the third embodiment.
"Readable data (O)" or "Unreadable data (x)" in the address blocks shown in FIGS. 15 and 16 are data # 1 to data #n (for example, n = 2048, total number of data 2048). This shows a state when the data constituting one sector indicated by is read in the “CD-ROM mode2 form2” format.
[0083]
In the state of FIG. 15 before overwriting, all the data # 1 to data #n are “readable data (◯)” that does not include an error after error correction processing of only CIRC, and an error occurs in the CD-ROM drive. It can be read without any problem.
[0084]
On the other hand, in the state of FIG. 16 after overwriting, after error correction processing of only CIRC, data # 1 and data # 4 are “readable data (◯)” including no error, data # 2, and data # 3. , Data # 5 to data #n are “unreadable data (×)” including errors that cannot be returned to the data before overwriting, “readable data (◯)” and “unreadable data” (×) ”is mixed. When data # 1 to data #n are read in this mixed state, “readable data (◯)” can be read with a correct value without error, but “unreadable data (×)” includes an error. It cannot be read as a correct value.
[0085]
By using the correctness of the read data, data of a predetermined value is recorded in advance as “correctable data (◯)” as a correct value before overwriting, and cannot be read as a correct value after overwriting. Focusing on the fact that it can be read as data having a value different from the predetermined value data, the fact that the correct value cannot be read is determined as “unreadable data (×)”.
[0086]
Further, as the predetermined value before overwriting, the sector address number of the address block, the value of the error-free portion, and the like can be used together with the predetermined value as necessary. As a result, in the third embodiment, data recorded in a predetermined data area of the address block is read as it is as a correct value or a value different from the correct value, so that the entire address block area is detected as unreadable. Compared to those of Example 1 and Example 2, the detection time can be greatly shortened (for example, 1/10 or less).
[0087]
[Example 4]
As shown in FIGS. 17, 18, and 19, the fourth embodiment of the present invention shows structures (1) to (3) of a recording format including application information that conforms to the CD-ROM format.
As shown in FIG. 17, the recording format structure (1) is a specific application example that conforms to the data structure shown in FIGS. 6 and 7 of the second embodiment, and includes a lead-in area and a program area (track). # 1) It consists of a lead-out area. The program area is composed of an application area, an address area, and a data area.
[0088]
The application area is an area for recording software of application information that controls writing and reading of data with respect to the data area (data # 1 to data # 3).
The address area is the same as the address block total (FIGS. 6, 15, and 16) described above. For example, packet # 1 to packet # 3 in FIG. 1 are used as data areas (data # 1 to data # 3). When used, the status of each address block (data area used / unused information, “readable data (○)”, “unreadable data (×)”) is concentrated and recorded here. This is a region (corresponding to FIG. 6).
[0089]
As shown in FIG. 18, the recording format structure (2) has a blank area between the data # 3 and the lead-out area in the medium format structure (1) (FIG. 17). equal.
The data area is composed of data # 1 to data # 3 and a blank area. This blank area is a blank area between the last additionally recorded data # 3 and the lead-out area and having no EFM recording information.
This blank area is determined in advance as an area not recorded by PW, and at least one of the size of the area, the sector address address of the block, and the presence / absence of the area can be used as identification information unique to the medium.
[0090]
As described above, since the packet recording according to the present invention includes the dummy block (FIG. 7), the light beam emitted from the optical pickup does not enter the blank area when the last additionally recorded data # 3 is reproduced by the CD-ROM drive. Therefore, the structure of FIG. 18 is possible.
[0091]
As shown in FIG. 19, the recording format structure (3) is the same as the medium format structure (1) (FIG. 17) excluding the lead-out area.
Also in this case, since the packet recording of the present invention includes the dummy block (FIG. 7), the light beam emitted from the optical pickup does not enter the blank area when the last additional data # 3 is reproduced by the CD-ROM drive. The structure of FIG. 19 becomes possible.
[0092]
The information without the lead-out area can be used as the medium identification information as in the format structure (2).
[0093]
[Example 5]
The fifth embodiment of the present invention is the structure (1) to (3) of the medium shown in FIGS. 20, 21, and 22, and a structure example for specifically developing the format of the above-described fourth embodiment on the medium. It is. The description of the fifth embodiment will be made by taking the structure (1) of the disk format of FIG. 17 of the fourth embodiment as an example. Although not described in detail here, it is a matter of course that the disk format structure (FIGS. 18 and 19) can be used.
[0094]
In the medium structure (1), as shown in FIG. 20, the entire area (lead-in area, program area (track # 1), lead-out area) is constituted by a CD-R medium.
[0095]
Here, the CD-R medium is formed by sequentially laminating a dye layer, a reflective layer, and a protective layer on a substrate on which spiral track grooves are engraved, and this dye layer has a predetermined level. Needless to say, it is formed by applying a dye whose transmittance cannot be restored by irradiation with a light beam having the above power.
[0096]
The medium having the above-described medium structure (1) is similar to the following medium structure (2) (FIG. 21) by adding necessary data to the lead-in area, application area, and lead-out area in advance. It is possible to have a functional structure, and by adding necessary data to the lead-in area and the lead-out area in advance, a functional structure similar to the disk structure (3) (FIG. 22) described below can be obtained. it can. The medium structure (1) is effective when the number of packet recordings, the packet size, etc. in the application area and the data area are undecided.
[0097]
Therefore, the medium having the medium structure (1) is smaller in the capacity of the application and the data area than the disk structure (2) (FIG. 21) and the disk structure (3) (FIG. 22) described below. Since each data recording capacity section can be arbitrarily set within the capacity range of all program areas according to the number and capacity of each area, it is the most versatile, the production process is the least, and the cost can be reduced, There is also an advantage in changing the space for inventory management after manufacturing.
[0098]
As shown in FIG. 21, the medium structure (2) includes a lead-in area and an application area in all areas (a lead-in area, a program area composed of an application area, an address area, and a data area, and a lead-out area). And a lead-out area is a CD-ROM area for recording by changing the physical depth of pits / lands, and an address area and a data area are CD-R areas.
This disk structure (2) is effective when the number of packet recordings in the application area and data area, the packet size, etc. are determined in advance.
[0099]
As shown in FIG. 22, the structure (3) of the medium has a lead-in area and a lead-out area in all areas (a lead-in area, a program area composed of an application area, an address area, and a data area, a lead-out area). This is a hybrid structure in which the area is a CD-ROM area and the other application area, address area, and data area are CD-R areas.
[0100]
This medium structure (3) is effective when the specifications of the application area and the data area are undecided but the specifications of the program area are fixed.
[0101]
In the above description, packet # 1 to packet # 3 (data # 1 to data # 3) have been described as examples, but it goes without saying that the present invention is not limited to such a number of packets (number of data). Yes.
[0102]
The present invention described above is expressed by CD-R and hybrid CD-R conforming to the CD standard. However, the present invention is not limited to this, and other disk media such as a recordable digital versatile disk ( Needless to say, the present invention can also be applied to DVD-R).
[0103]
【The invention's effect】
As described above in detail, the present invention, when appending information in accordance with the CD-R packet writing recording method, adds the appended packet information even in a state before finalization processing during packet writing. An optical information recording medium that can be read by a CD-ROM drive can be provided.
In addition, the present invention reads the appended packet information recorded on the optical information recording medium immediately by loading it in a CD-ROM drive attached to a general personal computer and setting it in a playback state, Since it can be confirmed, it can be delivered to a necessary department in a short time via a network of information read out via a personal computer.
[Brief description of the drawings]
FIG. 1 is a correspondence diagram of Embodiment 1 of the present invention, and an optical information recording medium in which additional recorded information cannot be read in the additional recording intermediate state shown in FIG. 14 can be read by a CD-ROM driver. It is a figure for demonstrating a solution.
FIG. 2 is a diagram illustrating a new packet recording format according to the first embodiment of the present invention.
3 is a diagram for explaining a recording state of an address block of a packet # 1 at the time of a first additional recording in which a packet # 1 is additionally recorded using the packet recording format of FIG. 2;
4 is a diagram for explaining a recording state of each address block of packet # 1 and packet # 2 in the second additional recording in which packet # 2 is additionally recorded using the packet recording format of FIG. 2; .
5 is a diagram for explaining a recording state of each address block from packet # 1 to packet # 3 at the time of the third additional recording in which packet # 3 is additionally recorded using the packet recording format of FIG. 2; is there.
FIG. 6 is a diagram corresponding to Example 2 of the present invention and for explaining a recording state of an address block in packet # 1.
FIG. 7 is a correspondence diagram of the second embodiment of the present invention, and is a diagram for explaining a recording format of a packet that does not include an address block in all packets # 2 to # 101 except packet # 1. .
FIG. 8 is a diagram illustrating a DAO recording format.
FIG. 9 is a diagram showing a SAO recording format.
FIG. 10 is a diagram showing a TAO recording format.
FIG. 11 is a diagram showing a PW recording format.
FIG. 12 is a diagram showing a packet recording format used in the PW system.
FIG. 13 is a diagram for explaining a state in the middle of additional writing before the finalizing process of the PW method.
14 is a diagram for explaining that additional information cannot be read by the CD-ROM drive from the CD-R in the additional recording state shown in FIG. 13; FIG.
FIG. 15 is a correspondence diagram of Embodiment 3 of the present invention and is a diagram for explaining a data structure of an address block before overwriting;
FIG. 16 is a diagram for explaining the data structure of an address block after overwriting, corresponding to Example 3 of the present invention.
FIG. 17 is a diagram corresponding to Example 4 of the present invention and for explaining the data format (1) of the recording format.
FIG. 18 is a diagram corresponding to Example 4 of the present invention and for explaining the data format (2) of the recording format.
FIG. 19 is a diagram corresponding to Example 4 of the present invention and for explaining a data format (3) of a recording format.
FIG. 20 is a diagram corresponding to Example 5 of the present invention and for explaining a structural example (1) of the optical information recording medium.
FIG. 21 is a diagram corresponding to Example 5 of the present invention and for explaining a structural example (2) of the optical information recording medium.
FIG. 22 is a diagram corresponding to Example 5 of the present invention and for explaining a structural example (3) of the optical information recording medium.
[Explanation of symbols]
A, B area (first area, second area)

Claims (4)

An optical information recording medium capable of sequentially adding information in accordance with a CD-R packet writing recording method in which a PCA, a PMA, a lead-in area, a program area, and a lead-out area are sequentially arranged,
A first region in which the PCA and the PMA are disposed;
A second area in which the lead-in area, the program area, and the lead-out area are arranged;
The program area is composed of at least one track,
The track is composed of at least one packet,
Each packet includes at least a user data block, an address block, and a dummy block,
In the lead-in area, at least information on the number of tracks, the start time of the track, and the lead-out start time is recorded in advance prior to all additional recordings,
At the end of this additional recording, the additional recording end information is recorded only in the address block in the final packet, and the additional recording end information recorded in the address block in the packet that became the final packet at the end of the previous additional recording is made unreadable,
An optical information recording medium characterized in that a packet having an address block from which additional recording end information can be read is determined as a final packet and additional recording is performed from a packet immediately after the final packet at the next additional recording start time. The optical information recording medium according to claim 1,
The address block of the first packet has the same number of blocks as the number of packets that can be additionally written after the second packet. An optical information recording medium according to claim 1 or 2,
At the end of this additional writing, the additional writing end information recorded in the address block corresponding to the last packet at the end of the previous additional writing is overwritten with a specific signal, thereby making it impossible to read the additional writing end information. An optical information recording medium. An optical information recording medium according to any one of claims 1 to 3,
The information recorded in the dummy block is
An optical information recording medium, characterized in that the information is information that enables the tracking servo operation on the reproducing apparatus side to be continued for a predetermined period after reading the address block in the final packet.

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