JP2012069209A - Optical information recording/reproducing method and recording/reproducing device, and control device of copy - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve the problem in which: for managed copy, if each disk of copy sources can be identified individually, information on how many times copies are made from the disk can be obtained and therefore various services will be realized, but a BCA (Burst Cutting Area), effective for identification of individual disks, needs recording for each disk with a laser, which leads to increase in manufacturing cost.SOLUTION: Processing of copy permission is switched depending on whether identification information of the optical disk is identification information which includes solid identification information or identification information which does not include solid identification information.

Description

  The present invention relates to an optical information recording method and a recording apparatus.

  As described in Non-Patent Document 1, at present, optical discs having a recording density of about 50 GB are commercialized for consumer use according to the Blu-ray Disc (trademark) standard using a blue-violet semiconductor laser. Non-Patent Document 1 also describes that Blu-ray Disc (trademark) adopts AACS (Advanced Access Content System) as a copy protection technique. Non-Patent Document 1 also describes a managed copy that manages to which device the content is copied under the control of AACS and permits the copy.

“Understanding Blu-ray HD DVD” (pages 122-127) Technical Review

  Regarding managed copy, if each copy source disk can be identified individually, it is possible to obtain information such as how many times the copy has been executed from the disk, and various services are considered possible. BCA is effective for individual identification, but there is a problem that the manufacturing cost increases because recording is performed with a laser for each sheet.

  The above problems are solved by the invention described in the claims.

  According to the present invention, the copy management apparatus switches processing depending on the presence / absence of an individual identification code. Therefore, optimum processing is possible in each case where there is an individual identification and when there is no individual identification. Further, since the copy apparatus sends information regarding the presence or absence of a solid identification code to the copy control apparatus, the copy management apparatus can be optimally controlled.

Block diagram of recorder and copy management apparatus according to the present invention Operational flow chart of disk copy management apparatus according to the present invention Operational flow chart of disk copy management apparatus according to the present invention Operation flowchart of the recorder according to the present invention BCA format diagram handled by the recorder according to the present invention BCA format diagram handled by the recorder according to the present invention Optical disk overview Structure diagram of single-layer ROM disk used in the present invention Structure diagram of double-layer ROM disk used in the present invention Structure diagram of recording layer of ROM disk used in the present invention Data frame structure diagram of disk used in the present invention Structure of scrambled data frame of disc used in the present invention Data block configuration diagram of 216 rows and 304 columns of the disk used in the present invention LDC block structure diagram of disk used in the present invention The block diagram which shows the 1st interleaving with respect to a LDC block The block diagram which shows the 2nd interleaving with respect to a LDC block Structure diagram of disk address information used in the present invention Structure diagram of disk access block used in the present invention Structure diagram of BIS block of disk used in the present invention Structure diagram of BIS cluster of disk used in the present invention Structural diagram of ECC cluster of disk used in the present invention Structure diagram of recording frame of disc used in the present invention Conversion diagram of 1-7 modulation used in the disk used in the present invention Sync signal pattern table for sync frames Structure diagram showing BCA position of disk used in the present invention Conversion table showing BCA modulation speed of disk used in the present invention The figure which shows the recording shape of BCA of the disk used for this invention Data structure diagram of BCA of disk used in the present invention BCA sync signal pattern table Configuration diagram of ECC block of BCA code BCA data block configuration diagram Block diagram of optical disc recording / reproducing apparatus used in the present invention Block diagram of back-end processing unit used in the present invention

[Disk copy device and copy management device]
A home recorder and copy management apparatus having an optical disk copy function according to an embodiment of the present application will be described with reference to FIGS. 1, 2, and 3. FIG. FIG. 1 is a block diagram of a home recorder and copy management apparatus having an optical disk copy function, which is an embodiment of the present application. FIG. 2 is a flowchart showing the operation of the home recorder having the optical disk copy function of FIG. FIG. 3 is a flowchart showing the operation of the copy management apparatus of FIG.

  First, the configuration of a home recorder having an optical disk copy function and a copy management apparatus will be described with reference to the block diagram of FIG. 101 is a home recorder having an optical disk copy function, 102 is a copy management device, and 108 is a display device. A home recorder 101 having an optical disc copy function includes an optical disc recording / reproducing unit 103, an HDD (Hard Disc Drive) unit 104, a back-end unit 105, a communication processing unit 106, and a copy controller 107. The copy management apparatus 102 includes a BCA Type determination unit 109, a copy permission determination unit 110, and a communication processing unit 111.

  The optical disc recording / reproducing unit 103 performs reproduction of a reproduction-only disc as a copy source and recording processing on a recordable disc as a copy destination. The HDD unit 104 temporarily records the reproduction data of the reproduction-only disc from the optical disc recording / reproducing unit 103, and reproduces the temporarily recorded data when the disc recording / reproducing unit 103 records on the recordable disc. The back-end unit 105 performs compression / decompression of a video signal. During recording, a signal from the external input terminal 122 (video), 123 (audio), or the tuner 112 is input to perform compression processing, stream Plex processing or the like is performed, and a recording stream is supplied to the optical disc recording / reproducing unit 103 or supplied to the HDD unit 104. The back-end unit 105 selects and inputs a playback signal from the optical disc recording / playback unit 103 or a playback signal from the HDD unit 104 at the time of playback, demultiplexes the input signal, and then performs audio and video Is then output to the display 108 via the audio signal output terminal 124 and the video signal output terminal 125. The audio signal output terminal and the video signal output terminal may be configured to output both from one output terminal as in HDMI. When the back end unit 105 temporarily records the reproduction data of the reproduction-only disc from the optical disc recording / reproducing unit 103 in the HDD unit 104, the back end unit 105 outputs the reproduction signal from the optical disc recording / reproducing unit 103 according to the copy permission signal of the copy controller 107. Then, a recording signal is supplied to the HDD unit 104. When the optical disc recording / reproducing unit 103 reproduces the BCA portion of the reproduction-only disc, the back end unit 105 is supplied with BCA information and BCA Type information from the optical disc recording / reproducing unit 103, and the BCA information is transmitted through the signal line 116 to the BCA type. Information is sent to the communication processing unit 106 via the signal line 117. The back-end unit 105 inputs a reproduction signal from the HDD unit 104 in accordance with a copy permission signal from the copy controller 107 when the temporary recording data of the HDD unit is recorded on a recordable disc by the disc recording / reproducing unit 103, and disc recording A recording signal is supplied to the reproduction unit 103. The communication processing unit 106 transmits the BCA information input from the back end unit 105, the BCA Type information, and the copy request signal input from the copy controller 107 to the copy management apparatus 102 via a communication line 128 such as the Internet. At the same time, the copy permission information from the copy management apparatus 102 is received via the communication line 128, and the copy permission information is sent to the copy controller 107. Further, the communication processing unit sends information related to copying such as a copy permission signal from the copy management apparatus 102 to the back-end unit 105 and displays it on the display 108 to the user. The copy controller 107 controls copying from the read-only disc to the recordable disc in the optical disc recording / playback unit 103 while exchanging with the copy management apparatus 102, and a copy request input by the user is copied from the terminal 120. The fee payment information input is input from the terminal 121, and the copy device identification information is sent to the copy management device 102 via the communication processing unit 106, and the back end unit 105 is controlled to control the BCA information and BCA Type information. A reproduction-only disc from the optical disc recording / reproducing unit 103 is transmitted to the copy management device 102 via the communication processing unit 106 and in accordance with a copy permission signal input from the copy management device 102 via the communication processing unit 106 Control of whether or not playback data can be temporarily recorded, HDD unit Temporary recording data for controlling the availability of that recorded in the recordable disk by the disk recording and reproducing unit 103.

  The display 108 includes a speaker that receives the video signal from the back-end unit 105 from the video signal output terminal 125 and displays the video signal, and receives the audio signal from the audio signal output terminal 124 and outputs it.

  The communication processing unit 111 outputs the BCA information, the copy request signal, the copy fee payment information, and the copy device identification number input via the communication line 128 such as the Internet to the copy permission determination unit 110, and performs communication such as the Internet. The BCA Type information input via the line 128 is output to the BCA Type determination unit 110, and the copy permission information input from the copy permission determination unit 110 is transmitted to the copy apparatus 101 via the communication line 128. The BCA Type determination unit 109 determines from the input BCA Type information whether the BCA of the reproduced disc is capable of solid identification for identifying each disc or whether identification is impossible. The determination result is sent to the copy permission determination unit 110. The copy permission determination unit 110 determines whether or not to permit individual identification by BCA, BCA information, copy fee payment information, and copy request, and outputs copy permission information to the communication processing unit 111.

Next, the operation of the optical disc management apparatus 102 will be described using the flowchart of FIG. When the process is started (201), first, a copy request 1 is received from the home recorder 101 having an optical disk copy function (202). This indicates that there was a copy request from the user. The copy request 1 signal is sent to the copy permission determination unit 110. When the copy request 1 is received, the copy permission determination unit 110 requests the BCA Type information and the BCA information from the home recorder 101 having the optical disk copy function via the communication processing unit 111 and the communication line 128 (203). In response to the request (203), BCA Type information and BCA information transmitted from a home recorder having an optical disk copy function are received (204). The BCA Type information is sent to the BCA Type determining unit 111, and the BCA information is sent to the copy permission determining unit 110. The BCA Type determination unit 109 determines whether the received BCA is discriminated for each disk, that is, whether individual identification is possible (205). If solid identification is possible, the copy permission determination unit 110 determines whether free copying is possible based on the BCA information (206). Assuming that free copies can be made n times (n: natural number) for one disk, if the number of free copies made in the past by the copy permission determination unit 110 is n or less, free copies can be made. To the effect, the information on the free copy offer is sent to the home quantity recorder 101, and if the offer is accepted, the process continues to step 213. If the number of times is greater than n, the free copy is not permitted. If the free copy is not permitted, the copy permission determination unit 110 determines whether the pay copy is permitted based on the BCA information (221). If it is determined that the pay copy is not allowed, the subsequent processing is continued from 217 onward. If it is determined that the pay copy is possible, the pay copy offer information is sent to the home quantity recorder 101 to the effect that the pay copy is possible. If accepted, the copy fee for the disc has already been paid, for example, the copy fee for 5 times has been paid in a lump, but the copy was actually made 3 times. That is, it is determined whether there is a balance for the disc in association with the BCA information (207). If there is a balance, processing 213 is continued. If there is no balance, a request for payment is made (208). Next, it is determined whether or not copying is possible based on whether or not the payment information indicating that the payment has been made in response to the payment request 208 has been received and the BCA information (209). If payment information has been received, the payment information is stored in the copy permission determination unit 110 (210), and the processing 213 is continued. If payment information is not received, processing 217 follows. If it is determined that the individual identification is impossible in the BCA Type determination process 205, it is impossible to know how many times the free copy has been performed for one disk, so the free copy determination 206 is skipped and 221 is charged. Judge whether copying is possible. From 222, 207 onward, the processing of the portion following the processing 213 or processing 217 is the same as the case where solid identification is possible. The description from the process 213 is continued. In the process 213, when processing is performed following 220, a message indicating that free copy is permitted, and when processing is performed following 207-Yes, a message indicating that copying is permitted due to the paid fee. , After 210, a message indicating that copying is permitted is sent to the home recorder 101 having a copy function of the optical disc, respectively, according to the fee for the current payment procedure. 214 receives the copy request signal 2 corresponding to the sent message. This is a final confirmation as to whether the user instructs execution of the permission message. After confirming the copy request signal 2 (214), a copy permission signal is sent from the copy permission determination unit 110 to the home recorder 101 having the optical disk copy function via the communication processing unit 111 and the communication line 128 (215). After the transmission of the copy permission signal (215), a history of whether the copy has been completed, that is, whether the free copy has been performed, the copy has been made with the paid fee, or the copy has been made with the fee for the current payment procedure is accumulated 216. The post-accumulation process is terminated (219).
The description of the processing from one processing 217 is continued. In process 217, a message indicating that copying is not permitted is sent to the home recorder 101 having the optical disc copy function. Thereafter, a copy non-permission signal is sent from the copy permission determination unit 110 to the home recorder 101 having the optical disk copy function via the communication processing unit 111 and the communication line 128 (218). After 218, the process ends.

  This copy management device distinguishes between discs that can be identified and discs that cannot be identified. For discs that can be identified, copy control including free copy is performed. Since copy control that does not include free copies is performed, it is possible to perform appropriate copy management even when disks capable of solid identification and disks that cannot be identified are mixed.

Next, another example of the operation of the optical disc management apparatus 102 will be described using the flowchart of FIG. The contents of each process in the flowchart in FIG. 3 are the same as those in the flowchart in FIG. 2 except for the transmission of the copy permission message 313.
Differences in the combination order of the processes in FIG. 3 from FIG. 2 and the processing contents of 313 will be described. First, regarding the difference in the combination order of each process, the process 206 and the process 221 are performed in parallel, not sequentially, in the case of solid identification. Next, the process 313 will be described. As the process 206 and the process 221 are processed in parallel, the copy permission message is “Yes” in each of the processes 206, 207, and 209, and a permission message for each is transmitted.

  Therefore, it is possible to make a copy permission decision based on the fee that has been paid, regardless of whether it is a paid copy or a free copy, and to make a copy decision based on the paid fee as a free copy. It can be done regardless. Therefore, the management process is easier to use for the user.

  Next, the operation of the home recorder having an optical disk copy function, which is an embodiment of the present invention, will be described with reference to the flowchart of FIG. When processing is started (401), it is first determined whether there is a copy request from the user (402). When the request is received, a check is made as to whether or not the disc cannot be played back due to factors such as scratches, and copying for rental etc. In the first place, it is checked whether the disk is not allowed (403). If copying is impossible as a result of the check, the processing is terminated (412). If the copy does not become impossible as a result of the check, a copy request signal 1 is transmitted (404) to the copy management apparatus 102 to indicate that the user intends to copy. Next, BCA Type information and BCA information are transmitted to the copy management apparatus 102 (405). At this time, an identification code of a home recorder having an optical disk copy function is also sent to the copy management apparatus 102. Next, a copy offer is received from the copy management apparatus 102 (423). When a free copy offer is received (421), if the user receives the offer, a request for free copy is returned according to the input from the user. (422), and the process proceeds to processing (420). If a free copy offer does not come and a paid copy offer is received (406), a paid copy request is issued according to the user's input (424), and if there is a further payment request, input from the user Accordingly, the payment information is transmitted to the copy management apparatus 102 (407). This doubles as a request for paid copying. On the other hand, copy permission / non-permission information is received (420), and permission / non-permission is determined from the copy permission information displayed on the display 108 (408). 412). If the copy is permitted, the copy request 2 is transmitted to the copy management apparatus 102 according to the final judgment input by the user (409). When the copy request 2 is transmitted (409), the reception of the copy permission signal from the copy management apparatus 102 is waited (410), and the reproduction-only medium is copied to the recording medium (411). After the copy process (411) ends, the entire process ends (412).

  As described above, according to the present embodiment, even if a disc capable of identifying solids and a disc capable of discriminating solids are mixed, information for distinguishing both is transmitted to the management device, so that recording can be performed from a read-only disc without any problem. Can be copied to a commercial disk.

  Next, the BCA data format of the read-only disc used in the present invention will be described. FIG. 5 shows a format of a data block used for BCA capable of individual identification. FIG. 6 shows the format of a data block used for both those that can be identified and those that cannot be identified.

  It is assumed that a disc according to the format of FIG. 5 already exists in the market, and that a reproduction-only disc according to the format of FIG. 6 is newly manufactured. In FIG. 5, the vertical byte indicates how many bytes of data, and the horizontal bit indicates how many bits of data. In FIG. 5, Byte 0 of BCA is a content code, of which Bit 7 to Bit 2 are identifiers (application IDs). In this case, it is assumed that 000001 is set. Bits 1 and 0 of Byte 0 are sequence numbers, and indicate the sequence number when the BCA is composed of a plurality of data blocks. The sequence number is also shown in the description of BCA described later. Byte1 and Byte2 are manufacturer identification codes. Byte 3 to Byte 15 are unique numbers added to each disk. In other words, it is a number that allows individual identification. In the format of FIG. 5, solid information sufficient to perform fine copy management can be obtained. However, it is necessary to assign a different number to each sheet and record it, which increases the manufacturing cost.

  In FIG. 6, the vertical byte indicates how many bytes of data, and the horizontal bit indicates what number of bits of data. In FIG. 5, Byte 0 of BCA is a content code, of which Bit 7 to Bit 2 are identifiers (application IDs). In this case, it is assumed that 000001 is set. Bits 1 and 0 of Byte 0 are sequence numbers, and indicate the sequence number when the BCA is composed of a plurality of data blocks. The sequence number is also shown in the description of BCA described later. Byte 1 of Byte 1 is a unique number (that is, a number that allows individual identification) to which Byte 3 to Byte 15 are added for each disk when 0, and for each group of managed disks (for example, general consumers) This is a number added to a disc for business use or a business use disc (that is, a number that cannot be identified individually). Byte 1 and Byte 2 except Byte 1 of Byte 1 are manufacturer identification codes. Byte 3 to Byte 15 are as described for Byte 1 of Bit 7. In the format of FIG. 6, solid information sufficient for fine copy management can be obtained, but both the production cost is increased and the copy management fineness is slightly reduced but the production cost can be reduced. It is possible to coexist. In addition, the content switching bit from Byte 3 to Byte 15 assigned to Byte 1 of Byte 1 is selected, but among the identification codes of the manufacturers of Byte 1 and Byte 2 in the format of FIG. 5, a bit that is not used in the assigned code is selected. Thus, the format of FIG. 5 and the format of FIG. 6 can coexist. Further, the same can be realized by assigning two types of manufacturer identification codes according to the contents of Bytes 3 to 15 without assigning a specific Bit as the switching bit of the contents of Byte 3 to 15.

[Disc shape]
The shape of the read-only disc used in the present invention will be described. FIG. 7 shows an overview of the optical disk. FIG. 8 shows a single-layer ROM (reproduction-only) disk. FIG. 9 shows a two-layer ROM (reproduction-only) disk. The single-layer ROM disk shown in FIG. 8 has a label surface on which a label is written and a recording surface on which a light beam for reproduction is incident. It consists of a cover layer that protects the recording surface from the recording surface side, a recording layer on which signals are recorded, and a base layer below it. The two-layer ROM disk shown in FIG. 9 also has a label surface on the side on which the label is written and a recording surface on the side on which the light beam for reproduction is incident. A cover layer that protects the recording surface from the recording surface side, a recording layer (L1) in which signals are recorded, a space layer that separates from another recording layer, and a recording layer (L0) in which another signal is recorded ) And the base layer below it.

  Next, the structure of the recording layer of the single-layer ROM disk and the double-layer ROM disk is shown in FIG. FIG. 10 schematically shows the cross section of the disc with the left side as the inner periphery and the right side as the outer periphery. FIG. 10A shows the disk structure of the recording layer L0 of the single-layer ROM disk and the double-layer ROM disk. FIG. 10B shows the disk structure of the recording layer L1 of the two-layer ROM disk.

  In FIG. 10A, in the L0 disk structure, reference numeral 1001 denotes a BCA (Burst Cutting Area), in which information unique to the disk is recorded. Reference numeral 1002 denotes an inner zone 0 in which attribute information and control information relating to the disc are recorded. Also referred to as Lead-in. Reference numeral 1003 denotes Data Zone 0, in which user data such as AV data is recorded. Reference numeral 1004 denotes an outer zone 0 in which control information and the like are recorded. Inner Zone 0 (1002) includes Protection Zone 1 (1005), PIC (1006), Protection Zone 2 (1007), INFO 02 (1008), reserved (1009), and INFO 01 (1010). Protection Zone 1 (1005) is an area for separating BCA (1001) and PIC (1006). The PIC (1006) is information regarding the type of disk, information regarding the size of the disk, information regarding the version of the disk, information regarding the structure of the disk, information regarding the channel bit length, information regarding the presence or absence of BCA, Information related to transmission speed is recorded. Protection Zone 2 (1007) is an area for separating PIC (1006) and INFO 02 (1008). Control information is recorded in INFO02 (1008). reserved (1009) is a reserved area. Control information is recorded in INFO01 (1010). Outer Zone 0 (1004) consists of INFO 3/4 (1011) and Protection Zone 3 (1012). Control information is recorded in INFO3 / 4 (1011). Protection Zone3 (1012) further separates INFO3 / 4 (1011) from the outer peripheral portion. In FIG. 10 (a), the arrow from the inner circumference to the outer circumference of the L0 disk structure indicates that the recording layer L0 of the single-layer ROM disk and the double-layer ROM disk is recorded so as to read from the inner circumference to the outer circumference. Indicates.

  In FIG. 10B, in the L1 disc structure, reference numeral 1014 denotes an inner zone 1 in which attribute information, control information, etc. relating to the disc are recorded. Also referred to as Lead-out. Reference numeral 1015 denotes Data Zone 0, in which user data such as AV data is recorded. Reference numeral 1016 denotes an outer zone 1 in which control information and the like are recorded. Inner Zone 1 (1014) includes Protection Zone 1 (1017), PIC (1018), Protection Zone 2 (1019), INFO 02 (1020), reserved (1021), and INFO 01 (1022). The protection zone 1 (1017) is an area for separating the inner peripheral side from the PIC (1018). The PIC (1018) is information regarding the type of disk, information regarding the size of the disk, information regarding the version of the disk, information regarding the structure of the disk, information regarding the channel bit length, information regarding the presence or absence of BCA, Information related to transmission speed is recorded. Protection Zone 2 (1019) is an area for separating PIC (1018) and INFO02 (1020). Control information is recorded in INFO02 (1020). “reserved” (1021) is a reserved area. Control information is recorded in INFO01 (1022). Outer Zone 1 (1016) is composed of INFO 3/4 (1023) and Protection Zone 3 (1024). Control information is recorded in INFO3 / 4 (1023). Protection Zone3 (1024) further separates INFO3 / 4 (1023) from the outer peripheral portion. In FIG. 10B, the arrow from the outer periphery to the inner periphery of the L1 disk structure indicates that the recording layer L1 of the dual-layer ROM disk is recorded so as to read from the outer periphery toward the inner periphery.

[Data encoding process]
User data recording processing will be described. As shown in FIG. 11, user data is divided into units of 2048 bytes, and an error detection code of 4 bytes is added to each to form a data frame of 2052 bytes. Next, each data frame is scrambled as shown in FIG. 12 to form a scrambled data frame. Next, as shown in FIG. 12, 32 scrambled data frames are collected. Next, rearrangement is performed in the order of columns to form a data block of 216 rows and 304 columns as shown in FIG. Then, as shown in FIG. 14, each column of the data block is encoded with a Reed-Solomon code of (248, 216, 32), and a parity of 32 bytes is added to newly add 248 rows and 304 columns of LDC (Long Distant Code) block. For the LDC block, the next first interleaving and second interleaving are processed. In the first interleave, as shown in FIG. 15a, rearrangement is performed so that even-numbered columns of data and subsequent odd-numbered columns of data are alternately sandwiched to form a block of 496 rows and 152 columns. In the second interleave, as shown in FIG. 15b, for the rearranged block of 496 rows and 152 columns, the first two rows are not shifted in units of two rows from the top, and the next two rows are shifted to the left by 3 bytes. The next two lines are shifted by 6 bytes, and the next two lines are shifted to the left by 9 bytes and rearranged to increase the shift amount by 3 bytes. The data subjected to the first interleave and the second interleave constitute an LDC cluster.

  On the other hand, the address added to this data block is generated as follows.

  As shown in FIG. 16, the data block is divided into 16 address units, and 9-byte address information is assigned to each. The breakdown of 9 bytes consists of a 4-byte address, 1-byte flag information, a 5-byte address, and a parity added to the flag information. This address is subjected to an interleaving process to form a 6 × 24 matrix. At the same time, 18 bytes of user control data and 32 units are arranged in a matrix of 24 rows and 24 columns.

  The matrix of 6 rows and 24 columns and the matrix of 24 rows and 24 columns are combined to form an access block of 30 rows and 24 columns shown in FIG. Each row of the access block is encoded with a Reed-Solomon code of (62, 33, 32), and a 32-byte parity is added to the BIS (Burst Indicating Subcode) block shown in FIG. Form. The BIS block data is rearranged to form a B96 cluster of 496 rows and 3 columns shown in FIG.

  The LDC cluster is divided into 38 columns, and BIS cluster data is inserted between the LDC clusters one by one to form the ECC cluster shown in FIG.

  A 20-bit frame synchronization signal is added to the head of 155 bytes of data in each row of the ECC cluster, and 155 bytes of data are divided into 25 bits at the beginning and 45 bits thereafter, and a DC control bit is inserted between them. The recording frame shown in FIG. The DC control bit is controlled so that the modulated DSV is close to zero.

The modulation of the recording frame data is 17 modulation according to the table shown in FIG. The frame synchronization signal is added using a 30 bits synchronization code as shown in FIG. In FIG. 23, # is 1 when the data after modulation before the synchronization code is terminated with 0000 or 00, and is 0 in other cases.
[BCA]
The arrangement of the BCA shown in FIG. 10 is shown in FIG. A burst cutting area (BCA) 2402 is formed concentrically in the radius 21.3 mm to 22.0 mm of the optical disc 2401. Reference numeral 2403 denotes a center hall. This BCA stores disc-specific information such as a disc ID or format information conforming to the disc. Such information occupies 4648 channel bits, whereas one revolution is approximately 4750 channel bits.

  A modulation method of data recorded in the burst cutting area 2402 is shown in FIG. In this modulation method, 2-bit data is modulated as 7-bit data. The modulated 7-bit data is composed of the first half 3 bits as a synchronization part and the second half 4 bits as a data part. The synchronization unit is composed of only “010”. In the data part, “1” is set to any one of the four bits, and “0” is set to the other bits. In FIG. 25, if the original data is “00”, the data part is modulated to “1000”. Similarly, the original data “01”, “10”, and “11” are modulated as data portions “0100”, “0010”, and “0001”, respectively.

  FIG. 26 schematically shows a state where the synchronization part and the data part are recorded in the burst cutting area 2402. In this case, data “0101000” is shown. In the case of bit “1”, a low reflectance part is formed. In the case of bit “0”, the low reflectivity portion is not formed, and the change in disc reflectivity is almost zero.

  The data structure recorded in the burst cutting area 2402 is shown in FIG. In FIG. 27, each row is composed of 5 bytes. The first byte of each line is a synchronization byte, and the last 4 bytes are data.

  The first line is a preamble, and is all 00h.

  Since the first synchronization byte is used only for the first line, it is possible to detect the start position of the BCA code by detecting this. Alternatively, it can be detected together with 00h data after the first synchronization byte. From the second line to the 33rd line, the area is divided in units of four lines. From the second line to the fifth line, 16-byte data of user data I0,0 to I0,15 is arranged. Subsequently, from the sixth line to the ninth line, a 16-byte parity C0,0 to C0,15 corresponding to the user data I0,0 to I0,15 from the second line to the fifth line is shown. Is placed. One ECC block is configured by the user data from the second row to the fifth row and the parity from the sixth row to the ninth row.

  Similarly, user data I1,0 to I1,15 are arranged from the 10th line to the 13th line, and parities C1,0 to C1,15 corresponding to the 14th line to the 17th line are arranged. The User data I2,0 to I2,15 are arranged from the 18th line to the 21st line, and parities C2,0 to C2,15 corresponding to the 22nd line to the 25th line are arranged. User data I3,0 to I3,15 are arranged from the 26th line to the 29th line, and parities C3,0 to C3,15 corresponding to the 30th line to the 33rd line are arranged.

The synchronization byte in the second to fifth lines is SB00. The synchronization byte from the sixth line to the ninth line is SB01. The synchronization byte from the 10th line to the 13th line is SB02. The synchronization byte from the 14th line to the 17th line is SB03. The synchronization byte from the 18th line to the 21st line is SB10. The synchronization byte from the 22nd line to the 25th line is SB11. The synchronization byte from the 26th line to the 29th line is SB12. The synchronization byte from the 30th line to the 33rd line is SB13. In the 34th row, no data is arranged and only the SB32 of the synchronization byte is arranged. The data in FIG. 27 shows data before being modulated in accordance with the modulation scheme in FIG. The amount of data is 166 bytes. (= 5 bytes × 4 rows × 8 sets + 5 bytes + 1 byte) This information is modulated to result in 4648 channel bits. (= 166 × 8 × 7/2)
A specific data string of the synchronization signal in FIG. 27 is shown in FIG. Note that the example of FIG. 28 is expressed as a modulated channel bit string. The 28-channel bit synchronization byte is composed of a 14-channel bit sync body and a 14-channel bit sync ID. The 14-channel bit sync body includes a 7-channel bit sync body 1 and a 7-channel bit sync body 2. The sync ID of 14 channel bits is composed of a sync ID 1 of 7 channel bits and a sync ID 2 of 7 channel bits.

  The sync body has a pattern that does not follow the original modulation rule described above. That is, as shown in FIG. 25, according to the present modulation rule, the synchronization unit should be “010”. However, the synchronization part of the sink body 2 is set to “001” which is different from “010”. Therefore, the synchronization byte can be identified from the data.

  The sync body 1 of each synchronization byte is “010 0001”, and the sync body 2 is “001 0100”. On the other hand, the sync ID has a different value for each synchronization byte, and this enables identification of the synchronization byte. Thus, since each synchronization byte is different, identification is possible.

  The structure of the ECC block of the BCA code is shown in FIG. As the ECC, a Reed-Solomon code of RS (248, 216, 33) is used. This is a Reed-Solomon code similar to the ECC block of FIG. However, in the ECC block of the BCA code, as shown in FIG. 29, the first 200 bytes are fixed data, and for example, FFh is used. The 16-byte data following the fixed data is regarded as substantial BCA user data. A parity of 36 bytes is calculated using 200 bytes of fixed data and 16 bytes of BCA data.

  Of the 216-byte data according to the present invention, the first 200 bytes are fixed data and are not recorded on the optical disk. Similarly, of the 32-byte parity, only the first 16-byte parities C0 to C15 are recorded on the optical disc 1, and the remaining 16-byte parities are not recorded. At the time of decoding, the same value is used as it is for the fixed data of 200 bytes. Also, 16-byte parity that is not recorded is decoded as an erasure flag. That is, among the 32 bytes of parity, the latter 16 bytes are processed as if the located parity has been lost. Even if ½ of the parity is lost, the original parity can be decoded because the position is known.

  Thus, by using the same RS (248, 216, 33) as the ECC of user data recorded in the user data area, it is possible to realize a very strong error correction capability even in BCA. In addition, since the configuration with the same hardware is possible, the circuit scale can be reduced and the cost can be reduced. Furthermore, only 32 bytes need be recorded, and the data capacity can be increased as compared with the case where all 248 bytes are recorded.

  Next, FIG. 30 shows the configuration of the BCA data block. In the present invention, four ECC blocks are recorded in the burst cutting area 2402. The 16-byte data of each ECC block is composed of a leading 1-byte content code followed by 15-byte content data. In the BCA content code, 6 bits from the first bit 7 to bit 2 are used as the application ID, and the last 2 bits, bit 1 and bit 0 are used as the sequence number.

  The optical disc recording / reproducing apparatus can record or reproduce data only to an optical disc having the decided application ID. For example, content encryption / decryption key information required for protecting content data can be recorded on a disc having a specific application ID.

  The sequence number is composed of 2 bits and is “00”, “01”, “10”, or “11”. When the content data of each ECC block is 14 bytes or less, each sequence number is set to “00”.

  Next, a content data storage method will be described. For example, when the same content data is stored as the content data of the first two ECC blocks among the four ECC blocks (in this case, the same content data with the same application ID is written twice). The sequence number of each ECC block is “00”. That is, when the same content data is recorded, the sequence numbers of the two ECC blocks are the same number.

  Subsequently, when 24 bytes of content data different from the application ID of the first ECC block are stored in the remaining two ECC blocks, the first sequence number is set to “00” and the sequence of the second ECC block. The number is “01”. In other words, when a plurality of ECC blocks are spanned, serial numbers are stored.

  As described above, since the application ID and the sequence number are recorded in each ECC block, it is possible to identify which ECC block stores the desired data and whether or not the multiple writing is performed. Is possible.

  Note that the BCA content code and content data of the data block of FIG. 30 correspond to I0,0 to I0,15 of the first ECC block of FIG.

[Disc recording / playback device]
FIG. 31 shows a description of a recording / reproducing apparatus that performs reproduction of a reproduction-only disc described for the shape, data encoding process, and BCA, and recording / reproduction of a recordable disc having a common format with the reproduction-only disc, as preferred in the present invention. To do. Further, the recording / reproducing apparatus shown in FIG. 31 corresponds to the optical disc recording / reproducing unit of the disc copying apparatus shown in FIG. FIG. 31 is a block diagram of the recording / reproducing apparatus. In FIG. 31, reference numeral 3100 denotes a read-only disk shown in FIGS. 8, 9, and 10, or a recordable disk having a generally common shape. Reference numeral 3101 denotes a disk motor that rotates the disk 3100, and 3102 denotes an optical pickup that irradiates the disk 3100 with laser light and detects reflected light to obtain a reproduction signal. 3102 performs recording by irradiating the disk 3100 with a laser beam having an appropriately shaped waveform during recording. Reference numeral 3103 denotes an analog front end that performs waveform shaping of a signal detected by the optical pickup 3102 and generation of a servo signal. Reference numeral 3104 denotes a demodulation processing circuit which performs binarization of the waveform-shaped signal, demodulation processing based on 1-7 modulation described in the data encoding processing, and the like. Reference numeral 3105 denotes a DRAM (Dynamic Random Access Memory), which is used for temporary storage of demodulated data, input / output data during correction processing, data before modulation processing, and the like. An error correction circuit (ECC) 3106 performs error correction processing on the demodulated data temporarily stored in the DRAM 3105 during reproduction processing, and performs error correction on input data temporarily stored in the DRAM 3105 during recording processing. A correction code is added. An interface circuit 3107 outputs data temporarily stored in the DRAM 105 from the output terminal 3114, stores input data from the input terminal 3113 in the DRAM 3105, or outputs an output terminal 3115 for BCA related information stored in the DRAM 3105. Interface processing such as output from. 3113 and 3115 can be shared. In addition, 3113, 3114, and 3115 can be shared by making them bidirectional. A modulation circuit 3108 performs a modulation process based on the 1-7 modulation described in the data encoding process on the data read from the DRAM 3105 during recording, and supplies the modulated data to an LDD (Laser Diode Driver) 3109. To do. At the time of recording, the LDD 3109 supplies a recording waveform suitable for recording to the optical pickup 3102 with respect to the modulation data, and the pickup 3102 performs recording by emitting light according to the recording waveform. Reference numeral 3110 denotes a BCA decoder, which decodes a BCA data block recorded according to the presence or absence of low reflectance as described in [BCA] when reproducing the BCA.

[Backend]
The configuration of the back end unit in the optical disc recorder that handles the AV stream in the recording / playback apparatus in FIG. 31 will be described with reference to FIG. FIG. 32 is a block diagram of the back-end processing unit. The back end unit corresponds to the back end unit 105 in FIG.

  An application format AV stream is input via an input IF 3201 at an input terminal 3210 from the optical disc recording / reproducing apparatus or an input terminal 3211 from the HDD. The depacketizer 3202 converts the AV stream in the application format read from the recording medium 3100 in FIG. 31 or the HDD 104 in FIG. 1 into a stream that can be processed by the demultiplexer 3203. The demultiplexer 3203 outputs, to the AV decoder 3204, system information such as a video stream, an audio stream, and AV synchronization that constitute a playback section (PlayItem) of the AV stream designated by the CPU 3209. The AV decoder 3204 decodes the video stream and the audio stream, and outputs the playback video signal and the playback audio signal from the corresponding terminals 3217 and 3218, respectively.

  The AV encoder 3205 encodes the video signal input from the input terminal 3219 and the audio signal input from the input terminal 3220, respectively, and the system information such as the encoded video stream, the encoded audio stream, and AV synchronization is multiplexed by the multiplexer 3206. Output to. The encoded video stream is, for example, MPEG (Moving Picture Expert Group) 2 format, H.264, or the like. The encoded audio stream is, for example, an audio stream encoded by the MPEG1 system, an audio stream encoded by the Dolby AC3 system (trademark), or the like. The multiplexer 3206 multiplexes the input video and audio streams based on the input system information, and outputs the multiplexed video and audio streams to the packetizer 3207. The multiplexed stream is, for example, an MPEG2 transport stream or an MPEG2 program stream. The source packetizer 19 encodes the input multiplexed stream into an AV stream composed of source packets in accordance with the application format of the recording medium 3100 in FIG. 31 that records the stream. The encoded AV stream is output from the output terminal 3224 to the optical disc recording / playback apparatus or the output terminal 3225 to the HDD via the output IF 3208.

  The BCA information and the BCA Type information are input from the input terminal 3212, sent to the CPU 3209 via the input IF 3201, the CPU 3209 separates the BCA Type information from the BCA information, and the BCA information and the BCA information via the output IF 3208 via the signal line 3225. BCA Type information is output from the output terminal 3226.

  DESCRIPTION OF SYMBOLS 101 ... Home recorder, 102 ... Copy management apparatus, 103 ... Optical disk recording / reproducing part, 105 ... Back end part, 107 ... Copy controller, 109 ... BCA Type determination part, 110 ... Copy permission determination part

Claims (9)

A copy management device that controls copying of content from an optical disc,
A copy management apparatus comprising: means for switching a copy permission process depending on whether the identification information of the optical disc is identification information including solid identification information or identification information not including solid identification information.   The switching of the copy permission process according to claim 1 selects a copy permission process including a free copy when the identification information includes solid identification information, and when the identification information does not include solid identification information. A copy management apparatus that selects a copy permission process that does not include a free copy. A copying apparatus for copying content from an optical disc,
An optical disc comprising: means for transmitting type information of identification information indicating whether the identification information of the optical disc is identification information including solid identification information or identification information not including solid identification information. Recording / playback device.   4. An optical disc recording / reproducing apparatus, wherein the identification information according to claim 3 is recorded in a BCA of the optical disc.   The identification information according to claim 3 and identification information type information indicating whether the identification information is identification information including solid identification information or identification information not including solid identification information is stored in the BCA of the optical disc. A recording / reproducing apparatus for an optical disc, which is recorded. A playback-only optical disc,
A read-only optical disc, wherein type information indicating whether the identification information includes solid identification information or identification information not including solid identification information is recorded on the BCA together with the identification information.   7. The read-only optical disc according to claim 6, wherein the type information according to claim 6 is recorded on a BCA using a recording area for manufacturer identification information. A copy management method for managing a copy of content from an optical disc,
A copy management method, wherein the copy permission process is switched depending on whether the identification information of the optical disc is identification information including solid identification information or identification information not including solid identification information.   The copy permission process according to claim 8, wherein when the identification information includes solid identification information, a copy permission process including a free copy is selected, and when the identification information does not include solid identification information. A copy management method, wherein a copy permission process not including a free copy is selected.

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