JP2005018842A - Reproducing device and method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To adequately control a buffer memory when using a disk-like recording medium for recording and reproducing at a larger unit than that of the buffer memory. <P>SOLUTION: The buffer memory is controlled by a disk image. The memory control is carried out in a cluster unit and also an access is carried out in a sector unit. The control area of the memory and the cluster of the disk are corresponded each other, and further a fill bit showing the validity/invalidity of data in the sector unit is corresponded. The reproduction of data recorded on the disk is requested in the sector unit, and the sector is converted to the cluster and the fill bit by a specific conversion formula. The data reproduced from the disk in a cluster unit are written into the memory. Data are taken out from the memory in the sector unit. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a memory control method and playback apparatus for controlling data transfer between storage media having different data recording unit sizes, and is particularly suitable for use in transferring continuous data such as audio data. The present invention relates to a memory control method and a playback device.
[0002]
[Prior art]
Conventionally, as a recording medium for recording and reproducing digital audio data, a mini disk (MD), which is a magneto-optical disk having a diameter of 64 mm, housed in a cartridge has been widely used. In the MD system, ATRAC (Adaptive Transform Acoustic Coding) is used as a compression method of audio data, and U-TOC (User TOC (Table Of Contents)) is used for music data management. That is, an area called U-TOC is provided on the inner periphery of the recordable area of the disc. The U-TOC is management information that is rewritten according to the order of tracks (audio tracks / data tracks), recording, erasure, etc. in the current MD system, and the start position of each track (parts constituting the track). It manages the end position and mode.
[0003]
In this way, the MD system uses a file management method that is different from a file system based on FAT (File Allocation Table), which is generally used in personal computers, and is therefore compatible with general-purpose computers such as personal computers. It wasn't. Therefore, a system has been proposed in which a general-purpose management system such as a FAT system is introduced to improve compatibility with a personal computer. In the FAT system, data is recorded and reproduced in units called FAT sectors. One sector is, for example, 2 kB (kilobytes), and a plurality of sectors gather to form a unit called a cluster.
[0004]
In order to absorb the speed difference between the recording / reproducing speed of the disk recording medium and the transfer rate of the audio data, particularly when performing continuous data recording / reproducing such as audio data using such a disk recording medium. The buffer memory control technology becomes important. Japanese Patent Application Laid-Open No. H10-228561 describes a technique that can output a monitor sound that can be heard during high-speed dubbing by controlling a buffer memory.
[0005]
[Patent Document 1]
JP 2002-245712 A
[0006]
In the MD system described above, one sector is 2 kB, and data can be recorded / reproduced in units of sectors. Therefore, even when the FAT system is introduced, compatibility at the time of recording and reproduction can be easily ensured.
[0007]
[Problems to be solved by the invention]
Here, the disk of the current MD system has a recording capacity of about 160 MB, and it is no longer possible to say that the capacity is large as the capacity of hard disk drives and optical disk media advances. Therefore, there is a need for a disk system with an increased recording capacity while ensuring compatibility with current MDs. In order to increase the capacity of the disk of the current MD system, it is necessary to improve the laser wavelength and the aperture ratio NA of the optical head. However, there is a limit to improving the laser wavelength and the aperture ratio NA of the optical head. Therefore, a system for increasing the capacity using a technique such as magnetic super-resolution has been proposed. In this system, data recording / reproduction is performed in units of clusters of, for example, 64 kB in consideration of efficient use of recording media and improvement of access speed.
[0008]
As described above, when using a recording medium that performs recording / reproduction with a size different from the recording / reproduction unit of the file system, it is necessary to devise a buffer memory control method. For example, when data read from a recording medium in cluster units is written to a buffer memory that can be written in sector units, the necessary data is inadvertently overwritten due to the size of the data to be written being larger than the recording / playback unit of the memory. It is necessary to take care not to mess up.
[0009]
Accordingly, an object of the present invention is to provide a reproducing apparatus and method for appropriately controlling a buffer memory when using a disk-shaped recording medium that performs recording / reproducing in a unit larger than the recording / reproducing unit of the buffer memory. There is.
[0010]
[Means for Solving the Problems]
In order to solve the above-described problem, the present invention provides a reproducing apparatus for reproducing data from a recording medium for reproducing data in a first data unit, and reproducing means for reproducing data from the recording medium in a first data unit. The memory space is managed in a unit corresponding to the first data unit, the memory accessible in a second data unit smaller than the first data unit, the address on the memory, and the first data unit of the recording medium And a correspondence table associating the fill information indicating whether the data is valid for the memory space management unit corresponding to the address of the memory in the second data unit, and the data reproduced by the reproducing means in the memory based on the fill information And a memory control means for writing.
[0011]
According to another aspect of the present invention, there is provided a reproduction method for reproducing data from a recording medium for reproducing data in a first data unit, a reproduction step for reproducing data from the recording medium in a first data unit, and a first data unit. The memory space is managed in a unit corresponding to the memory address, the memory address that is accessible in the second data unit smaller than the first data unit, the first data unit of the recording medium, and the memory corresponding to the memory address Associating fill information indicating whether or not data is valid in the second data unit with respect to the space management unit, and a memory control step of writing the data reproduced in the reproduction step into the memory based on the fill information Is a reproduction method characterized by the above.
[0012]
As described above, according to the present invention, the memory space is managed in a unit corresponding to the first data unit, the address on the memory accessible in the second data unit smaller than the first data unit, the recording medium The first data unit cluster is associated with the fill information indicating in the second data unit whether or not the data is valid for the memory space management unit corresponding to the address of the memory by the correspondence table, and the first data is recorded from the recording medium. Since the data reproduced in units is written in the memory based on the fill information, the data written in the memory is written in the second data unit based on the correspondence between the address on the memory of the correspondence table and the fill information. Can be read.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below. Prior to the description of the embodiment of the present invention, a disk system applicable to the present invention will be described according to the following 10 sections.
1. Overview of recording method
2. About discs
3. Signal format
4). Configuration of recording / playback device
5. About disk initialization processing by next generation MD1 and next generation MD2
6). About the first management method of music data
7. Second example of music data management system
8). Operation when connected to a personal computer
9. Memory control method
[0014]
1. Overview of recording method
In the recording / reproducing apparatus according to the present invention, a magneto-optical disk is used as a recording medium. The physical attributes of the disk, such as the form factor, are substantially the same as the disks used by so-called MD (Mini-Disc) systems. However, the data recorded on the disc and how the data is arranged on the disc is different from the conventional MD.
[0015]
More specifically, the apparatus according to the present invention uses a FAT (File Allocation Table) system as a file management system in order to record and reproduce content data such as audio data. As a result, the apparatus can guarantee compatibility with the current personal computer.
[0016]
Here, the term “FAT” or “FAT system” is used generically to refer to various PC-based file systems, as described above, and the specific FAT base used in DOS (Disk Operating System). File system, VFAT (Virtual FAT) used in Windows95 / 98 (each registered trademark), FAT32 used in Windows98 / ME / 2000 (each registered trademark), and NTFS (also called NT File System (New Technology File System) )) Is not intended to indicate any of the above. NTFS is a file system used in the Windows NT (registered trademark) operating system or (optionally) Windows 2000, and records and retrieves files when reading / writing to / from a disk.
[0017]
In the present invention, the error correction method and the modulation method are improved with respect to the current MD system to increase the data recording capacity and improve the data reliability. Furthermore, according to the present invention, the content data is encrypted and illegal copying is prevented to protect the copyright of the content data.
[0018]
As a recording / reproducing format, the specification of the next generation MD1 using a disk (that is, a physical medium) exactly the same as the disk used in the current MD system, and the disk used in the current MD system. The form factor and external shape are the same, but there is a next-generation MD2 specification that uses magnetic super-resolution (MSR) technology to increase the recording density in the linear recording direction and further increase the recording capacity. Developed by the present inventors.
[0019]
In the current MD system, a magneto-optical disk having a diameter of 64 mm housed in a cartridge is used as a recording medium. The disc has a thickness of 1.2 mm, and a center hole having a diameter of 11 mm is provided at the center thereof. The cartridge has a length of 68 mm, a width of 72 mm, and a thickness of 5 mm.
[0020]
The shape of the disc and the shape of the cartridge are all the same in the specifications of the next generation MD1 and the specification of the next generation MD2. Regarding the start position of the lead-in area, the next-generation MD1 specification and the next-generation MD2 specification disc start from 29 mm and are the same as the disc used in the current MD system.
[0021]
Regarding the track pitch, in the next generation MD2, it is considered to be 1.2 μm to 1.3 μm (for example, 1.25 μm). On the other hand, in the next generation MD1, which uses a disk of the current MD system, the track pitch is set to 1.6 μm. The next-generation MD1 is 0.44 μm / bit and the next-generation MD2 is 0.16 μm / bit. The redundancy is 20.50% for both the next generation MD1 and the next generation MD2.
[0022]
In the next-generation MD2 specification disk, the recording capacity in the linear density direction is improved by using a magnetic super-resolution technique. In the magnetic super-resolution technology, when a predetermined temperature is reached, the cut layer becomes magnetically neutral, and the magnetic wall transferred to the reproducing layer moves, so that a minute mark appears large in the beam spot. It is a thing using what becomes.
[0023]
That is, in the next-generation MD2 specification disk, a magnetic layer serving as a recording layer for recording information, a cutting layer, and a magnetic layer for reproducing information are stacked on a transparent substrate. The cutting layer is an exchange coupling force adjusting layer. When the temperature reaches a predetermined temperature, the cut layer becomes magnetically neutral, and the domain wall transferred to the recording layer is transferred to the reproducing magnetic layer. As a result, minute marks can be seen in the beam spot. At the time of recording, a minute mark can be generated by using a laser pulse magnetic field modulation technique.
[0024]
In addition, in the next-generation MD2 specification disc, the groove is made deeper than conventional MD discs to improve the detrack margin, crosstalk from the land, crosstalk of the wobble signal, and leakage of focus. It is sharp. In the disc of the next generation MD2 specification, the groove depth is, for example, 160 nm to 180 nm, the groove inclination is, for example, 60 degrees to 70 degrees, and the groove width is, for example, 600 nm to 700 nm.
[0025]
As for the optical specifications, the laser wavelength λ is 780 nm and the aperture ratio NA of the objective lens of the optical head is 0.45 in the next generation MD1 specification. Similarly, in the specification of the next generation MD2, the laser wavelength λ is 780 nm, and the aperture ratio NA of the optical head is 0.45.
[0026]
As a recording method, the groove recording method is adopted for both the next generation MD1 specification and the next generation MD2 specification. That is, the groove (groove on the disk surface of the disk) is used as a track for recording and reproduction.
[0027]
As an error correction coding method, a convolutional code based on Advanced Cross Interleaved Reed-Solomon Code (ACIRC) is used in the current MD system. A block-complete code combining a Solomon-Long Distance Code (B) and a BIS (Burst Indicator Subcode) is used. By adopting a block completion type error correction code, a linking sector becomes unnecessary. In an error correction method combining LDC and BIS, an error location can be detected by BIS when a burst error occurs. Using this error location, erasure correction can be performed by the LDC code.
[0028]
As an addressing method, a wobbled groove method is used in which a single spiral groove is formed and wobbles as address information are formed on both sides of the groove. Such an address system is called ADIP (Address in Pregroove). The specifications of the current MD system and the next generation MD1 and the next generation MD2 have different line densities, and the current MD system uses a convolutional code called ACIRC as an error correction code. In the specifications of the generation MD1 and the next generation MD2, since a block completion type code combining LDC and BIS is used, the redundancy is different and the relative positional relationship between ADIP and data is changed. Therefore, in the specification of the next generation MD1, which uses a disk having the same physical structure as that of the current MD system, the handling of the ADIP signal is made different from that in the current MD system. In the next-generation MD2 specification, the specification of the ADIP signal is changed so as to match the specification of the next-generation MD2.
[0029]
Regarding the modulation method, EFM (8 to 14 Modulation) is used in the current MD system, whereas in the specifications of the next generation MD1 and the next generation MD2, RLL (1, 7) PP (RLL; Run) Length Limited, PP; Parity Preserve / Prohibit rmtr (repeated minimum transition run) (hereinafter referred to as 1-7pp modulation) is employed. The data detection method is a Viterbi decoding method using a partial response PR (1, 2, 1) ML in the next generation MD1 and a partial response PR (1, -1) ML in the next generation MD2. .
[0030]
In addition, the disk drive system is CLV (Constant Linear Velocity) or ZCAV (Zone Constant Angular Velocity), and the standard linear velocity is 2.4 m / sec in the next generation MD1 specification, and in the next generation MD2 specification, 1.98 m / sec. In the specification of the current MD system, it is 1.2 m / second for a 60-minute disk and 1.4 m / second for a 74-minute disk.
[0031]
In the specification of the next generation MD1, which uses the disk used in the current MD system as it is, the total data recording capacity per disk is about 300 Mbytes (when an 80-minute disk is used). By changing the modulation method from EFM to 1-7pp modulation, the window margin is changed from 0.5 to 0.666, and in this respect, a 1.33 times higher density can be realized. Further, since the error correction method is a combination of BIS and LDC from the ACIRC method, the data efficiency is improved, and in this respect, 1.48 times higher density can be realized. Overall, a data capacity of about twice that of the current MD system was realized using exactly the same disk.
[0032]
In the next-generation MD2 specification disk using magnetic super-resolution, the recording density is further increased in the linear density direction, and the total data recording capacity is about 1 Gbyte.
[0033]
The data rate is 4.4 Mbit / sec for the next generation MD1 and 9.8 Mbit / sec for the next generation MD2 at the standard linear velocity.
[0034]
2. About discs
FIG. 1 shows the configuration of the next-generation MD1 disc. The next-generation MD1 disc is a disc of the current MD system. That is, the disk is configured by laminating a dielectric film, a magnetic film, a dielectric film, and a reflective film on a transparent polycarbonate substrate. Further, a protective film is laminated thereon.
[0035]
In the disc of the next generation MD1, as shown in FIG. 1, the inner circumference of the disc (the innermost circumference of the recordable area of the disc (“innermost” indicates the innermost side in the direction extending radially from the center of the disc)) In the lead-in area, a P-TOC (pre-mastered TOC (Table Of Contents)) area is provided, which is a pre-mastered area as a physical structure. For example, it is recorded as P-TOC information.
[0036]
The outer periphery of the lead-in area in which the P-TOC area is provided (the outer periphery in the direction extending radially from the center of the disk) is a recordable area (a magneto-optical recording area), and a groove is formed as a guide groove for a recording track. It is a formed recordable / reproducible area. A U-TOC (user TOC) is provided on the inner periphery of the recordable area.
[0037]
The U-TOC has the same configuration as the U-TOC used for recording disc management information in the current MD system. The U-TOC is management information that is rewritten according to the order of tracks (audio tracks / data tracks), recording, erasure, etc. in the current MD system, and the start position of each track (parts constituting the track). It manages the end position and mode.
[0038]
An alert track is provided on the outer periphery of the U-TOC. This track records a warning sound that is activated (output) by the MD player when the disc is loaded into the current MD system. This warning sound indicates that the disc is used in the next generation MD1 system and cannot be reproduced by the current system. The remaining portion of the recordable area (shown in detail in FIG. 2) extends radially to the lead-out area.
[0039]
FIG. 2 shows the structure of the recordable area of the disc of the next generation MD1 specification shown in FIG. As shown in FIG. 2, a U-TOC and an alert track are provided at the beginning (inner circumference side) of the recordable area. In the area including the U-TOC and the alert track, the data is modulated by EFM and recorded so that it can be reproduced by a player of the current MD system. An area where data is modulated and recorded by 1-7pp modulation of the next generation MD1 system is provided on the outer periphery of the area where the data is modulated and recorded by EFM modulation. The area where data is modulated and recorded by EFM and the area where data is modulated and recorded by 1-7pp modulation are separated by a predetermined distance, and a “guard band” is provided. Yes. Since such a guard band is provided, it is possible to prevent the occurrence of problems by mounting a disc of the next generation MD1 specification on the current MD player.
[0040]
A DDT (Disc Description Table) area and a reserve track are provided at the head (inner circumference side) of an area where data is modulated and recorded by 1-7pp modulation. The DDT area is provided in order to perform a replacement process for a physically defective area. In the DDT area, an identification code unique to each disk is further recorded. Hereinafter, the identification code unique to each disk is referred to as UID (unique ID). In the case of the next-generation MD1, the UID is generated based on, for example, a predetermined random number, and is recorded, for example, when the disc is initialized (details will be described later). By using the UID, it is possible to perform security management for the recorded contents of the disc. The reserve track stores information for protecting the content.
[0041]
Furthermore, a FAT (File Allocation Table) area is provided in an area where data is modulated and recorded by 1-7pp modulation. The FAT area is an area for managing data in the FAT system. The FAT system performs data management conforming to the FAT system used in general-purpose personal computers. The FAT system performs file management by a FAT chain using a directory indicating entry points of files and directories at the root and a FAT table in which FAT cluster connection information is described. Note that the terminology of FAT is generally used to indicate various different file management methods used in the PC operating system as described above.
[0042]
In the disc of the next generation MD1 specification, information on the start position of the alert track and information on the start position of the area where the data is modulated by 1-7pp modulation are recorded in the U-TOC area.
[0043]
When the next-generation MD1 disc is loaded into the player of the current MD system, the U-TOC area is read, the position of the alert track is known from the U-TOC information, the alert track is accessed, and the alert track Playback starts. In the alert track, a warning sound is recorded indicating that this disc is used in the next generation MD1 system and cannot be reproduced by a player of the current MD system. This warning sound informs that this disc cannot be used with current MD system players.
[0044]
The warning sound may be a warning in a language such as “cannot be used with this player”. Of course, a simple beep, tone, or other warning signal may be used.
[0045]
When a next-generation MD1 disc is loaded into a player compliant with the next-generation MD1, the U-TOC area is read, and the start position of the area where data is recorded by 1-7pp modulation is determined from the U-TOC information. Okay, DDT, reserve track, FAT area is read. In the data area of 1-7pp modulation, data management is performed using the FAT system without using the U-TOC.
[0046]
FIG. 3 shows a next-generation MD2 disc. The disk is configured by laminating a dielectric film, a magnetic film, a dielectric film, and a reflective film on a transparent polycarbonate substrate. Further, a protective film is laminated thereon.
[0047]
In the next-generation MD2 disc, as shown in FIG. 3A, control information is recorded by an ADIP signal in the lead-in area on the inner circumference of the disc (the inner circumference in the direction extending radially from the center of the disc). . Next-generation MD2 discs are not provided with P-TOC by embossed pits in the lead-in area, and instead, control information by ADIP signals is used. The recordable area starts from the outer periphery of the lead-in area, and is a recordable / reproducible area in which a groove is formed as a guide groove for a recording track. In this recordable area, data is modulated and recorded by 1-7 pp modulation.
[0048]
In the disc of the next generation MD2 specification, as shown in FIG. 3B, a magnetic layer 101 serving as a recording layer for recording information, a cutting layer 102, and a magnetic layer 103 for reproducing information are stacked as magnetic films. Things are used. The cutting layer 102 is an exchange coupling force adjusting layer. When the temperature reaches a predetermined temperature, the cutting layer 102 becomes magnetically neutral, and the domain wall transferred to the recording layer 101 is transferred to the reproducing magnetic layer 103. As a result, a minute mark appears enlarged in the beam spot of the reproducing magnetic layer 103 on the recording layer 101.
[0049]
Although not shown, the above-mentioned UID is pre-recorded in an area that can be reproduced by a consumer recording / reproducing apparatus, but cannot be recorded, on the inner circumference side of the recordable area on a disc using the next generation MD2. The In the case of the next-generation MD2 disc, the UID is recorded in advance when the disc is manufactured by a technique similar to the technique of BCA (Burst Citting Area) used in, for example, a DVD (Digital Versatile Disc). Since the UID is generated and recorded when the disc is manufactured, the UID can be managed, and the security can be improved as compared with the case where the UID is generated based on a random number when the disc is initialized by the next generation MD1. Details of the format of the UID will be described later.
[0050]
In order to avoid complexity, this area where the UID is recorded in advance in the next generation MD2 will be referred to as BCA hereinafter.
[0051]
Whether it is the next generation MD1 or the next generation MD2 can be determined from, for example, lead-in information. That is, if a P-TOC due to an emboss pit is detected in the lead-in, it can be determined that the disc is a current MD or next-generation MD1 disc. If control information based on the ADIP signal is detected in the lead-in and P-TOC due to the emboss pit is not detected, it can be determined that the next generation MD2. It is also possible to determine whether or not a UID is recorded in the BCA described above. The discrimination between the next generation MD1 and the next generation MD2 is not limited to such a method. It is also possible to discriminate from the phase of the tracking error signal between on-track and off-track. Of course, a disc identification detection hole or the like may be provided.
[0052]
FIG. 4 shows the configuration of the recordable area of the disc of the next-generation MD2 specification. As shown in FIG. 4, in the recordable area, data is modulated and recorded with 1-7pp modulation, and DDT is recorded at the head (inner circumference side) of the area where data is modulated with 1-7pp modulation and recorded. An area and a reserve track are provided. The DDT area is provided for recording replacement area management data for managing a replacement area for a physically defective area.
[0053]
Specifically, the DDT area records a management table for managing a replacement area including a recordable area that replaces the physically defective area. This management table records the logical clusters determined to be defective, and also records the logical cluster (s) in the replacement area assigned as a replacement for the defective logical cluster. Further, the above-described UID is recorded in the DDT area. The reserve track stores information for protecting the content.
[0054]
Furthermore, a FAT area is provided in an area where data is modulated and recorded by 1-7pp modulation. The FAT area is an area for managing data in the FAT system. The FAT system performs data management conforming to the FAT system used in general-purpose personal computers.
[0055]
The U-TOC area is not provided in the next-generation MD2 disc. When a next-generation MD2 disc is loaded into a player compliant with the next-generation MD2, the DDT, reserve track, and FAT area at predetermined positions are read, and data management is performed using the FAT system.
[0056]
The next generation MD1 and next generation MD2 discs do not require time-consuming initialization work. In other words, the next generation MD1 and next generation MD2 specification discs require no initialization work other than the creation of minimum tables such as DDT, reserve track, and FAT table, and recordable areas can be recorded from unused discs. Reproduction can be performed directly.
[0057]
As described above, since the UID is generated and recorded at the time of manufacturing the disc as described above, the next-generation MD2 disc can perform security management more strongly, while being used in the disc used in the current MD system. Compared to this, the number of laminated films is larger and more expensive. Therefore, the recordable area and lead-in / lead-out area of the disc are the same as those of the next generation MD1, and only the UID is recorded at the time of manufacturing the disc in the same manner as the next generation MD2 using the same BCA as the DVD. A disk system (referred to as next generation MD1.5) has been proposed.
[0058]
In the following, the description of the next generation MD1.5 will be omitted unless particularly required. That is, the next generation MD1.5 conforms to the next generation MD2 with respect to the UID, and conforms to the next generation MD1 with respect to recording and reproduction of audio data.
[0059]
The UID will be described in more detail. As described above, in the next-generation MD2 disc, the UID is recorded in advance when the disc is manufactured by a technique similar to the technique called BCA used in the DVD. FIG. 5 schematically shows an example format of this UID. The entire UID is called a UID record block.
[0060]
In the UID block, the 2 bytes from the beginning are used as the UID code field. In the UID code, the upper 4 bits of 2 bytes, that is, 16 bits are used for disc identification. For example, when these 4 bits are [0000], it indicates that the disk is a next-generation MD2 disk, and [0001] indicates that the disk is a next-generation MD1.5 disk. Other values of the upper 4 bits of the UID code are reserved for future expansion, for example. The lower 12 bits of the UID code are an application ID and can correspond to 4096 types of services.
[0061]
Next to the UID code, a 1-byte version number field is arranged, and then, a 1-byte data length field is arranged. This data length indicates the data length of the field of the UID record data arranged next to the data length. The field of UID record data is arranged for 4 m (m = 0, 1, 2,...) Bytes within a range where the data length of the entire UID does not exceed 188 bytes. A unique ID generated by a predetermined method can be stored in the field of UID record data, thereby making it possible to identify a disc individual.
[0062]
In the next-generation MD1 disc, an ID generated based on a random number is recorded in the field of the UID record data.
[0063]
A plurality of UID record blocks can be created with a data length of up to 188 bytes.
[0064]
3. Signal format
Next, the signal format of the next generation MD1 and next generation MD2 system will be described. In the current MD system, ACIRC, which is a convolutional code, is used as an error correction method, and a sector of 2352 bytes corresponding to the data amount of a subcode block is used as an access unit for recording and reproduction. In the case of a convolutional code, since an error correction coding sequence spans a plurality of sectors, it is necessary to prepare a linking sector between adjacent sectors when data is rewritten. As an address method, ADIP, which is a wobbled groove method in which wobbling as address information is formed on both sides of a groove after forming a groove by a single spiral, is used. In the current MD system, ADIP signals are arranged so as to be optimal for accessing a sector of 2352 bytes.
[0065]
On the other hand, in the specifications of the next-generation MD1 and next-generation MD2 systems, a block-complete code combining LDC and BIS is used, and 64 Kbytes are used as a recording / reproduction access unit. In a block-complete code, no linking sector is required. Therefore, in the specification of the next generation MD1 system that uses the current MD system disk, the handling of the ADIP signal is changed so as to correspond to the new recording method. Further, in the specification of the next-generation MD2 system, the specification of the ADIP signal is changed so as to match the specification of the next-generation MD2.
[0066]
FIGS. 6, 7, and 8 are for explaining error correction methods used in the next-generation MD1 and next-generation MD2 systems. In the next-generation MD1 and next-generation MD2 systems, an error correction coding method using LDC as shown in FIG. 6 and a BIS method as shown in FIGS. 7 and 8 are combined.
[0067]
FIG. 6 shows a configuration of a coding block for error correction coding by LDC. As shown in FIG. 6, an error detection code EDC of 4 bytes is added to the data of each error correction encoding sector, and the data is stored in an error correction encoding block of 304 bytes in the horizontal direction and 216 bytes in the vertical direction. Are two-dimensionally arranged. Each error correction coding sector consists of 2K bytes of data. As shown in FIG. 6, an error correction coding block consisting of 304 bytes in the horizontal direction and 216 bytes in the vertical direction has 32 sectors of error correction coding sectors consisting of 2K bytes. Thus, 32-bit error correction is performed in the vertical direction for the data of the 32 error-correction coding sector error correction coding blocks that are two-dimensionally arranged in 304 bytes in the horizontal direction and 216 bytes in the vertical direction. The parity of Reed-Solomon code is added.
[0068]
7 and 8 show the configuration of the BIS. As shown in FIG. 7, 1 byte of BIS is inserted for every 38 bytes of data, and (38 × 4 = 152 bytes) of data, 3 bytes of BIS data, and 2.5 bytes of frame sync. A total of 157.5 bytes is taken as one frame.
[0069]
As shown in FIG. 8, the BIS block is configured by collecting 496 frames configured as described above. BIS data (3 × 496 = 1488 bytes) includes 576 bytes of user control data, 144 bytes of address unit number, and 768 bytes of error correction code.
[0070]
As described above, since the 768-byte error correction code is added to the 1488-byte data in the BIS data, it is possible to perform error correction strongly. By embedding this BIS code every 38 bytes, an error location can be detected when a burst error occurs. Using this error location, erasure correction can be performed by the LDC code.
[0071]
As shown in FIG. 9, the ADIP signal is recorded by forming wobbles on both sides of the single spiral groove. That is, the ADIP signal has FM-modulated address data and is recorded by being formed as a groove wobble on the disk material.
[0072]
FIG. 10 shows the sector format of the ADIP signal in the case of the next generation MD1.
[0073]
As shown in FIG. 10, one sector (ADIP sector) of the ADIP signal includes a 4-bit sync, an upper bit of the 8-bit ADIP cluster number, a lower bit of the 8-bit ADIP cluster number, and an 8-bit ADIP. It consists of a sector number and a 14-bit error detection code CRC.
[0074]
The sync is a signal having a predetermined pattern for detecting the head of the ADIP sector. Since the conventional MD system uses a convolutional code, a linking sector is required. The sector number for linking is a sector number having a negative value and is a sector number of “FCh”, “FDh”, “FEh”, “FFh” (h indicates a hexadecimal number). In the next generation MD1, since the disc of the current MD system is used, the format of this ADIP sector is the same as that of the current MD system.
[0075]
In the next-generation MD1 system, as shown in FIG. 11, an ADIP cluster is composed of 36 sectors from ADIP sector numbers “FCh” to “FFh” and “0Fh” to “1Fh”. Then, as shown in FIG. 10, data of two recording blocks (64 Kbytes) are arranged in one ADIP cluster.
[0076]
FIG. 12 shows the configuration of the ADIP sector in the case of the next generation MD2. In the specification of the next generation MD2, the ADIP sector is composed of 16 sectors. Therefore, the sector number of ADIP can be expressed by 4 bits. In the next-generation MD, since a block-complete error correction code is used, a linking sector is unnecessary.
[0077]
As shown in FIG. 12, the next generation MD2 ADIP sector includes a 4-bit sync, an upper bit of the 4-bit ADIP cluster number, a middle bit of the 8-bit ADIP cluster number, and a 4-bit ADIP cluster number. Lower bits, a 4-bit ADIP sector number, and an 18-bit parity for error correction.
[0078]
The sync is a signal having a predetermined pattern for detecting the head of the ADIP sector. As the ADIP cluster number, 16 bits of upper 4 bits, middle 8 bits, and lower 4 bits are described. Since the ADIP cluster is composed of 16 ADIP sectors, the sector number of the ADIP sector is 4 bits. In the current MD system, it is a 14-bit error detection code, but it is an 18-bit parity for error correction. In the next generation MD2 specification, as shown in FIG. 13, one recording block (64 Kbytes) of data is arranged in one ADIP cluster.
[0079]
FIG. 14 shows the relationship between ADIP clusters and BIS frames in the case of the next generation MD1.
[0080]
As shown in FIG. 11, according to the specification of the next generation MD1, 36 ADAD sectors “FC” to “FF” and ADIP sectors “00” to “1F” constitute one ADIP cluster. Two pieces of data of one recording block (64 Kbytes) serving as a recording / reproducing unit are arranged in one ADIP cluster.
[0081]
As shown in FIG. 14, one ADIP sector is divided into the first 18 sectors and the second 18 sectors.
[0082]
Data of one recording block as a recording / reproduction unit is arranged in a BIS block composed of 496 frames. A preamble of 10 frames (frame “0” to frame “9”) is added before the data frame (frame “10” to frame “505”) corresponding to the BIS block, and Then, a postamble frame of 6 frames (frame 506 to frame 511) is added to the frame of this data, and a total of 512 frames of data is an ADIP cluster of ADIP sector “FCh” to ADIP sector “0Dh”. And the second half of the ADIP cluster from ADIP sector “0Eh” to ADIP sector “1Fh”. The preamble frame before the data frame and the postamble frame after the data are used to protect the data when linking with the adjacent recording block. The preamble is also used for pulling in a data PLL, signal amplitude control, signal offset control, and the like.
[0083]
The physical address for recording / reproducing data of the recording block is specified by the ADIP cluster and the first half or the second half of the cluster. When a physical address is designated at the time of recording / reproduction, the ADIP sector is read from the ADIP signal, the ADIP cluster number and the ADIP sector number are read from the reproduction signal of the ADIP sector, and the first half and the second half of the ADIP cluster are discriminated.
[0084]
FIG. 15 shows the relationship between an ADIP cluster and a BIS frame in the case of the next-generation MD2 specification. As shown in FIG. 13, in the next generation MD2 specification, there are 16 ADIP sectors and one ADIP cluster is configured. One recording block (64 Kbytes) of data is arranged in one ADIP cluster.
[0085]
As shown in FIG. 15, data of one recording block (64 Kbytes) serving as a recording / reproduction unit is arranged in a BIS block composed of 496 frames. A preamble of 10 frames (frame “0” to frame “9”) is added before the data frame (frame “10” to frame “505”) corresponding to the BIS block, and Then, a postamble frame of 6 frames (frame 506 to frame 511) is added after the frame of this data, and a total of 512 frames of data is ADIP consisting of ADIP sector “0h” to ADIP sector “Fh”. Placed in a cluster.
[0086]
The preamble frame before the data frame and the postamble frame after the data are used to protect the data when linking with the adjacent recording block. The preamble is also used for pulling in a data PLL, signal amplitude control, signal offset control, and the like.
[0087]
A physical address when recording / reproducing data of a recording block is designated by an ADIP cluster. When a physical address is designated at the time of recording / reproduction, the ADIP sector is read from the ADIP signal, and the ADIP cluster number is read from the reproduction signal of the ADIP sector.
[0088]
By the way, in such a disc, various control information is necessary to control the laser power and the like when recording / reproduction is started. As shown in FIG. 1, the next-generation MD1 disc has a P-TOC in the lead-in area, and various control information is acquired from the P-TOC.
[0089]
Next-generation MD2 specification discs are not provided with P-TOC by embossed pits, and control information is recorded by ADIP signals in the lead-in area. In addition, since the magnetic super-resolution technology is used in the next-generation MD2 specification disk, laser power control is important. In the disc of the next generation MD2 specification, calibration areas for power control adjustment are provided in the lead-in area and the lead-out area.
[0090]
That is, FIG. 16 shows the lead-in and lead-out configuration of the disc of the next-generation MD2 specification. As shown in FIG. 16, in the lead-in and lead-out areas of the disk, a power calibration area is provided as a laser beam power control area.
[0091]
In the lead-in area, a control area in which control information by ADIP is recorded is provided. The recording of control information by ADIP describes the control information of the disc using the area allocated as the lower bits of the ADIP cluster number.
[0092]
That is, the ADIP cluster number starts from the start position of the recordable area and has a negative value in the lead-in area. As shown in FIG. 16, the ADIP sector of the next generation MD2 includes a 4-bit sync, an upper bit of the 8-bit ADIP cluster number, 8-bit control data (lower bits of the ADIP cluster number), 4-bit It consists of an ADIP sector number and an 18-bit error correction parity. As shown in FIG. 16, control information such as a disk type, magnetic phase, intensity, and read power is described in 8 bits assigned as lower bits of the ADIP cluster number.
[0093]
Since the upper bits of the ADIP cluster are left as they are, the current position can be known with a certain degree of accuracy. Further, the ADIP sector “0” and the ADIP sector “8” can accurately know the ADIP cluster at a predetermined interval by leaving the lower 8 bits of the ADIP cluster number.
[0094]
The recording of the control information by the ADIP signal is described in detail in the specification of Japanese Patent Application No. 2001-123535 previously proposed by the present applicant.
[0095]
4). Configuration of recording / playback device
Next, the configuration of a disk drive device (recording / reproducing apparatus) corresponding to a disk used for recording / reproducing in the next-generation MD1 and next-generation MD2 systems will be described with reference to FIGS.
[0096]
FIG. 17 shows that the disk drive device 1 can be connected to, for example, a personal computer 100.
[0097]
The disk drive device 1 includes a media drive unit 2, a memory transfer controller 3, a cluster buffer memory 4, an auxiliary memory 5, USB (Universal Serial Bus) interfaces 6 and 8, a USB hub 7, a system controller 9, and an audio processing unit 10. ing.
[0098]
The media drive unit 2 performs recording / reproduction with respect to the loaded disk 90. The disk 90 is a next-generation MD1 disk, a next-generation MD2 disk, or a current MD disk. The internal configuration of the media drive unit 2 will be described later with reference to FIG.
[0099]
The memory transfer controller 3 controls delivery of playback data from the media drive unit 2 and recording data supplied to the media drive unit 2.
[0100]
The cluster buffer memory 4 performs buffering of data read from the data track of the disk 90 by the media drive unit 2 in units of recording blocks based on the control of the memory transfer controller 3.
[0101]
The auxiliary memory 5 stores various management information and special information read from the disk 90 by the media drive unit 2 based on the control of the memory transfer controller 3.
[0102]
The system controller 9 connects a CPU (Central Processing Unit), a RAM (Random Access Memory) used as a work memory of the CPU, a ROM (Read Only Memory) in which programs and data are stored in advance, and the CPU, RAM, and ROM. For controlling the entire inside of the disk drive device 1 and the communication control with the connected personal computer 100 based on a program stored in the ROM.
[0103]
That is, the system controller 9 can communicate with the personal computer 100 connected via the USB interface 8 and the USB hub 7, receives commands such as write requests and read requests, status information, and other necessary information. And so on.
[0104]
For example, the system controller 9 instructs the media drive unit 2 to read management information from the disk 90 when the disk 90 is loaded into the media drive unit 2, and the management information read by the memory transfer controller 3. Is stored in the auxiliary memory 5.
[0105]
When there is a request to read a FAT sector from the personal computer 100, the system controller 9 causes the media drive unit 2 to read a recording block including the FAT sector. The read recording block data is written into the cluster buffer memory 4 by the memory transfer controller 3.
[0106]
The system controller 9 performs control to read out the requested FAT sector data from the recording block data written in the cluster buffer memory 4 and transmit it to the personal computer 100 via the USB interface 6 and the USB hub 7. .
[0107]
When there is a write request for a certain FAT sector from the personal computer 100, the system controller 9 first causes the media drive unit 2 to read the recording block including the FAT sector. The read recording block is written into the cluster buffer memory 4 by the memory transfer controller 3.
[0108]
The system controller 9 supplies the FAT sector data (record data) from the personal computer 100 to the memory transfer controller 3 via the USB interface 6 and rewrites the data of the corresponding FAT sector on the cluster buffer memory 4. Let
[0109]
The system controller 9 instructs the memory transfer controller 3 to transfer the recording block data stored in the cluster buffer memory 4 with the necessary FAT sector being rewritten to the media drive unit 2 as recording data. In the media drive unit 2, the recording data of the recording block is modulated and written to the disk 90.
[0110]
A switch 50 is connected to the system controller 9. The switch 50 sets the operation mode of the disk drive device 1 to either the next generation MD1 system or the current MD system. In other words, the disk drive apparatus 1 can record audio data on the disk 90 of the current MD system in both the current MD system format and the next-generation MD1 system format. The switch 50 can explicitly indicate the operation mode of the disk drive device 1 main body to the user. Although a mechanical switch is shown, a switch utilizing electricity or magnetism, or a hybrid type switch may be used.
[0111]
For the disk drive device 1, a display 51 made of, for example, an LCD (Liquid Crystal Display) is provided. The display 51 can display text data, simple icons, and the like, and displays information related to the state of the disk drive device 1 and a message to the user based on a display control signal supplied from the system controller 9.
[0112]
The audio processing unit 10 includes an analog audio signal input unit such as a line input circuit / microphone input circuit, an A / D converter, and a digital audio data input unit as an input system. The audio processing unit 10 includes an ATRAC compression encoder / decoder and a buffer memory for compressed data. Furthermore, the audio processing unit 10 includes an analog audio signal output unit such as a digital audio data output unit and a D / A converter and a line output circuit / headphone output circuit as an output system.
[0113]
When the disc 90 is a current MD disc, digital audio data (or an analog audio signal) is input to the audio processing unit 10 when an audio track is recorded on the disc 90. The input linear PCM digital audio data or the linear PCM audio data obtained by converting the analog audio signal and converting it by the A / D converter is subjected to ATRAC compression encoding and stored in the buffer memory. Then, the data is read from the buffer memory at a predetermined timing (data unit corresponding to the ADIP cluster) and transferred to the media drive unit 2. In the media drive unit 2, the transferred compressed data is modulated by EFM and written on the disk 90 as an audio track.
[0114]
When the disc 90 is a disc of the current MD system, when the audio track of the disc 90 is reproduced, the media drive unit 2 demodulates the reproduction data into the ATRAC compressed data state and transmits the audio via the memory transfer controller 3. Transfer to the processing unit 10. The audio processing unit 10 performs ATRAC compression decoding to obtain linear PCM audio data, which is output from the digital audio data output unit. Alternatively, line output / headphone output is performed as an analog audio signal by a D / A converter.
[0115]
The connection with the personal computer 100 is not USB, and other external interfaces such as IEEE (Institut of Electrical and Electronics Engineers) 1394 may be used.
[0116]
Recording / reproduction data management is performed using a FAT system, and conversion between recording blocks and FAT sectors is described in detail in the specification of Japanese Patent Application No. 2001-289380 previously proposed by the present applicant. .
[0117]
Next, the configuration of the media drive unit 2 having the function of recording and reproducing both the data track and the audio track will be described with reference to FIG.
[0118]
FIG. 18 shows the configuration of the media drive unit 2. The media drive unit 2 has a turntable on which a current MD system disc, a next generation MD1 disc, and a next generation MD2 disc are loaded. In the media drive unit 2, the turntable is loaded on the turntable. The disk 90 is rotated by the spindle motor 29 in the CLV method. The disc 90 is irradiated with laser light from the optical head 19 during recording / reproduction.
[0119]
The optical head 19 performs a high level laser output for heating the recording track to the Curie temperature during recording, and a relatively low level laser output for detecting data from reflected light by the magnetic Kerr effect during reproduction. . For this reason, the optical head 19 is mounted with a laser diode as a laser output means, an optical system composed of a polarizing beam splitter, an objective lens, etc., and a detector for detecting reflected light, although detailed illustration is omitted here. Yes. The objective lens provided in the optical head 19 is held so as to be displaceable in a radial direction of the disk and a direction in which it is in contact with or separated from the disk, for example, by a biaxial mechanism.
[0120]
A magnetic head 18 is disposed at a position facing the optical head 19 with the disk 90 interposed therebetween. The magnetic head 18 performs an operation of applying a magnetic field modulated by the recording data to the disk 90. Although not shown, a sled motor and a sled mechanism are provided to move the entire optical head 19 and the magnetic head 18 in the disk radial direction.
[0121]
In the case of the next-generation MD2 disk, the optical head 19 and the magnetic head 18 can form minute marks by performing pulse drive magnetic field modulation. In the case of a current MD disc or a next-generation MD1 disc, a DC light-emission magnetic field modulation method is used.
[0122]
In the media drive unit 2, a recording processing system, a playback processing system, a servo system, and the like are provided in addition to the recording / reproducing head system using the optical head 19 and the magnetic head 18 and the disk rotation driving system using the spindle motor 29.
[0123]
As the disk 90, there is a possibility that a current MD specification disk, a next generation MD1 specification disk, and a next generation MD2 specification disk may be mounted. These disks have different linear velocities. The spindle motor 29 can be rotated at a rotational speed corresponding to a plurality of types of disks having different linear velocities. The disc 90 loaded on the turntable is rotated according to the linear velocity of the current MD specification disc, the linear velocity of the next generation MD1 specification disc, and the linear velocity of the next generation MD2 specification disc. The
[0124]
In a recording processing system, in the case of a disc of the current MD system, when recording an audio track, error correction coding is performed with ACIRC, data is recorded by being modulated with EFM, and next generation MD1 or next generation MD2 In some cases, a part for performing error correction coding by a combination of BIS and LDC and modulating and recording with 1-7pp modulation is provided.
[0125]
The playback processing system uses EFM demodulation and ACIRC error correction processing during playback of the current MD system disc, and data detection using partial response and Viterbi decoding during playback of the next generation MD1 or next generation MD2 system disc. A portion for performing 1-7 demodulation based on the above and error correction processing by BIS and LDC is provided.
[0126]
Further, there are provided a part for decoding an address based on an ADIP signal of the current MD system or the next generation MD1, and a part for decoding an ADIP signal of the next generation MD2.
[0127]
Information (photocurrent obtained by detecting the laser reflected light by the photodetector) detected as reflected light by the laser irradiation of the optical head 19 on the disk 90 is supplied to the RF amplifier 21.
[0128]
The RF amplifier 21 performs current-voltage conversion, amplification, matrix calculation, and the like on the input detection information, and performs reproduction RF signal, tracking error signal TE, focus error signal FE, groove information (track on the disk 90) as reproduction information. ADIP information recorded by wobbling) is extracted.
[0129]
When reproducing the disc of the current MD system, the reproduced RF signal obtained by the RF amplifier is processed by the EFM demodulator 24 and the ACIRC decoder 25. That is, the reproduced RF signal is binarized by the EFM demodulator 24 to be converted into an EFM signal sequence, EFM demodulated, and further subjected to error correction and deinterleave processing by the ACIRC decoder 25. That is, at this time, the state becomes ATRAC compressed data.
[0130]
At the time of reproducing the disk of the current MD system, the selector 26 is selected on the B contact side, and the demodulated ATRAC compressed data is output as reproduced data from the disk 90.
[0131]
On the other hand, when reproducing the next-generation MD1 or next-generation MD2 disc, the reproduced RF signal obtained by the RF amplifier is processed by the RLL (1-7) PP demodulator 22 and the RS-LDC decoder 23. That is, the reproduced RF signal is detected by the RLL (1-7) PP demodulator 22 by means of data detection using PR (1, 2, 1) ML or PR (1, -1) ML and Viterbi decoding. ) Reproduced data as a code string is obtained, and RLL (1-7) demodulation processing is performed on this RLL (1-7) code string. Further, the RS-LDC decoder 23 performs error correction and deinterleave processing.
[0132]
When reproducing the next-generation MD1 or next-generation MD2 disc, the selector 26 is selected on the A contact side, and the demodulated data is output as reproduction data from the disc 90.
[0133]
The tracking error signal TE and the focus error signal FE output from the RF amplifier 21 are supplied to the servo circuit 27, and the groove information is supplied to the ADIP demodulator 30.
[0134]
The ADIP demodulator 30 performs band limitation on the groove information by a bandpass filter to extract a wobble component, and then performs FM demodulation and biphase demodulation to demodulate the ADIP signal. The demodulated ADIP signal is supplied to the address decoder 32 and the address decoder 33.
[0135]
In the disk of the current MD system or the disk of the next generation MD1, the ADIP sector number is 8 bits as shown in FIG. On the other hand, in the next-generation MD2 system disk, as shown in FIG. 12, the ADIP sector number is 4 bits. The address decoder 32 decodes the ADIP address of the current MD or the next generation MD1. The address decoder 33 decodes the address of the next generation MD2.
[0136]
The ADIP address decoded by the address decoders 32 and 33 is supplied to the drive controller 31. The drive controller 31 executes a required control process based on the ADIP address. The groove information is supplied to the servo circuit 27 for spindle servo control.
[0137]
The servo circuit 27 generates a spindle error signal for CLV or CAV servo control, for example, based on an error signal obtained by integrating a phase error with a reproduction clock (PLL clock at the time of decoding) with respect to groove information. .
[0138]
Further, the servo circuit 27 performs various servo control signals (tracking control signals) based on a spindle error signal, a tracking error signal supplied from the RF amplifier 21, a focus error signal, a track jump command, an access command, etc. from the drive controller 31. , A focus control signal, a thread control signal, a spindle control signal, etc.) are generated and output to the motor driver 28. That is, various servo control signals are generated by performing necessary processing such as phase compensation processing, gain processing, and target value setting processing on the servo error signal and command.
[0139]
The motor driver 28 generates a required servo drive signal based on the servo control signal supplied from the servo circuit 27. The servo drive signal here includes a biaxial drive signal for driving the biaxial mechanism (two types of focus direction and tracking direction), a sled motor drive signal for driving the sled mechanism, and a spindle motor drive signal for driving the spindle motor 29. It becomes. By such servo drive signals, focus control and tracking control for the disk 90 and CLV or CAV control for the spindle motor 29 are performed.
[0140]
When recording audio data on the disc of the current MD system, the selector 16 is connected to the B contact, so that the ACIRC encoder 14 and the EFM modulator 15 function. In this case, the compressed data from the audio processing unit 10 is subjected to interleaving and error correction code addition by the ACIRC encoder 14 and then EFM modulation by the EFM modulation unit 15.
[0141]
The EFM modulation data is supplied to the magnetic head driver 17 via the selector 16, and the magnetic head 18 applies a magnetic field to the disk 90 based on the EFM modulation data, thereby recording an audio track.
[0142]
When data is recorded on the next-generation MD1 or next-generation MD2 disc, the selector 16 is connected to the A contact, so that the RS-LDC encoder 12 and the RLL (1-7) PP modulation unit 13 function. In this case, the high-density data from the memory transfer controller 3 is subjected to interleaving and RS-LDC error correction code addition by the RS-LDC encoder 12, and then RLL (1-7) PP modulation unit 13 performs RLL (1 -7) Modulation is performed.
[0143]
Then, recording data as an RLL (1-7) code string is supplied to the magnetic head driver 17 via the selector 16, and the magnetic head 18 applies a magnetic field to the disk 90 based on the modulation data, so that the data track is recorded. Recording is performed.
[0144]
The laser driver / APC 20 causes the laser diode to perform a laser emission operation during reproduction and recording as described above, but also performs a so-called APC (Automatic Laser Power Control) operation.
[0145]
That is, although not shown, a detector for laser power monitoring is provided in the optical head 19 and the monitor signal is fed back to the laser driver / APC 20. The laser driver / APC 20 compares the current laser power obtained as the monitor signal with the set laser power and reflects the error in the laser drive signal, so that the laser power output from the laser diode is , It is controlled to stabilize at the set value.
[0146]
As the laser power, values as reproduction laser power and recording laser power are set in a register in the laser driver / APC 20 by the drive controller 31.
[0147]
Based on an instruction from the system controller 9, the drive controller 31 performs control so that the above operations (access, various servos, data writing, and data reading operations) are executed.
[0148]
In FIG. 18, the A part and the B part surrounded by the alternate long and short dash line can be configured as a one-chip circuit part, for example.
[0149]
5. About disk initialization processing by next generation MD1 and next generation MD2
As described above, a UID (unique ID) is recorded outside the FAT on the discs of the next generation MD1 and the next generation MD2, and security management is performed using the recorded UID. In principle, discs compatible with the next generation MD1 and the next generation MD2 are shipped with a UID recorded in advance on a predetermined position on the disc. In the disc corresponding to the next generation MD1, the UID is recorded in advance in the lead-in area, for example. In this case, the position where the UID is recorded in advance is not limited to the lead-in area. For example, if the position where the UID is written after initialization of the disk is fixed, it can be recorded in advance at that position. In the disc corresponding to the next generation MD2 and the next generation MD1.5, the UID is recorded in advance in the BCA described above.
[0150]
On the other hand, a disk based on the current MD system can be used as the disk based on the next generation MD1. For this reason, a number of discs based on the current MD system that have already been circulated without being recorded are used as discs for the next generation MD1.
[0151]
Therefore, an area that is protected by the standard is provided for a disk according to the current MD system that has been circulated without recording a UID, and the disk drive device 1 is provided in the area when the disk is initialized. The random number signal is recorded at, and this is used as the UID of the disc. Also, it is prohibited by the standard that the user accesses the area where this UID is recorded. The UID is not limited to a random number signal. For example, a manufacturer code, a device code, a device serial number, and a random number can be combined and used as a UID. Furthermore, any one or more of a manufacturer code, a device code, and a device serial number and a random number can be combined and used as a UID.
[0152]
FIG. 19 is a flowchart showing an example of initialization processing of a disk by the next generation MD1. In a first step S100, a predetermined position on the disc is accessed and it is confirmed whether a UID is recorded. If it is determined that the UID is recorded, the UID is read out and temporarily stored in the auxiliary memory 5, for example.
[0153]
The position accessed in step S100 is outside the FAT area of the format by the next generation MD1 system, such as the lead-in area. If the disk 90 is already provided with a DDT, such as a disk that has been initialized in the past, the area may be accessed. Note that the process of step S100 can be omitted.
[0154]
Next, in step S101, the U-TOC is recorded by EFM modulation. At this time, information for ensuring an alert track and a track after the DDT in FIG. 2, that is, an area where data is modulated and recorded by 1-7pp modulation is written to the U-TOC. In the next step S102, an alert track is recorded by EFM modulation in the area secured by the U-TOC in step S101. In step S103, DDT is recorded by 1-7pp modulation.
[0155]
In step S104, the UID is recorded in an area outside the FAT, for example, the DDT. If the UID is read from a predetermined position on the disk and stored in the auxiliary memory 5 in step S100 described above, the UID is recorded. If it is determined in step S100 that the UID is not recorded at a predetermined position on the disc, or if step S100 is omitted, a UID is generated based on the random number signal. This generated UID is recorded. The UID is generated by, for example, the system controller 9, and the generated UID is supplied to the media drive 2 via the memory transfer controller 3 and recorded on the disk 90.
[0156]
Next, in step S105, data such as FAT is recorded in an area where data is modulated by 1-7pp modulation and recorded. That is, the area where the UID is recorded is an area outside the FAT. Further, as described above, in the next generation MD1, initialization of the recordable area to be managed by the FAT is not necessarily required.
[0157]
FIG. 20 is a flowchart showing an example of initialization processing of a disc by the next generation MD2 and the next generation MD1.5. In the first step S110, an area corresponding to the BCA on the disc is accessed to check whether a UID is recorded. If it is determined that the UID is recorded, the UID is read out and temporarily stored in the auxiliary memory 5, for example. Since the recording position of the UID is fixedly determined on the format, it can be directly accessed without referring to other management information on the disc. This can also be applied to the processing described with reference to FIG.
[0158]
In the next step S111, the DDT is recorded by 1-7pp modulation. Next, in step S112, the UID is recorded in an area outside the FAT, for example, DDT. As the UID recorded at this time, the UID read from the predetermined position on the disk and stored in the auxiliary memory 5 in step S110 is used. If it is determined in step S110 described above that no UID is recorded at a predetermined position on the disc, a UID is generated based on the random number signal, and the generated UID is recorded. The UID is generated by, for example, the system controller 9, and the generated UID is supplied to the media drive 2 via the memory transfer controller 3 and recorded on the disk 90.
[0159]
In step S113, FAT or the like is recorded. That is, the area where the UID is recorded is an area outside the FAT. Further, as described above, in the next generation MD2, initialization of the recordable area to be managed by the FAT is not performed.
[0160]
6). About the first management method of music data
As described above, in the next generation MD1 and next generation MD2 systems to which the present invention is applied, data is managed by the FAT system. The audio data to be recorded is compressed by a desired compression method and encrypted to protect the rights of the author. As a method for compressing audio data, for example, it is considered to use ATRAC3, ATRAC5, or the like. Of course, other compression methods such as MP3 (MPEG1 Audio Layer-3) and AAC (MPEG2 Advanced Audio Coding) can also be used. Further, not only audio data but also still image data and moving image data can be handled. Of course, since the FAT system is used, general-purpose data can be recorded and reproduced. In addition, computer readable and executable instructions can be encoded on the disk, so that the next generation MD1 or next generation MD2 can also contain executable files.
[0161]
A management method for recording / reproducing audio data on / from the next generation MD1 and next generation MD2 discs will be described.
[0162]
In the next-generation MD1 system and the next-generation MD2 system, music data with high sound quality can be played back for a long time, so the number of music pieces managed on one disc is enormous. Moreover, the compatibility with a computer is achieved by managing using a FAT system. According to the recognition of the inventor of the present application, there is a merit that the usability can be improved, but the music data is illegally copied and there is a possibility that the copyright holder cannot be protected. In the management system to which the present invention is applied, consideration is given to such points.
[0163]
FIG. 21 is a first example of an audio data management method. As shown in FIG. 21, in the management method in the first example, a track index file and an audio data file are generated on the disc. The track index file and the audio data file are files managed by the FAT system.
[0164]
As shown in FIG. 22, the audio data file is a file in which a plurality of music data is stored as one file. When the audio data file is viewed with the FAT system, it looks like a huge file. The audio data file is partitioned as parts, and the audio data is handled as a set of parts.
[0165]
The track index file is a file in which various information for managing music data stored in the audio data file is described. As shown in FIG. 23, the track index file includes a play order table, a programmed play order table, a group information table, a track information table, a parts information table, and a name table.
[0166]
The play order table is a table indicating the playback order defined by default. As shown in FIG. 24, the play order table stores information TINF1, TINF2,... Indicating the link destination to the track descriptor (FIG. 27) of the track information table for each track number (song number). The track number is a continuous number starting from “1”, for example.
[0167]
The programmed play order table is a table in which each user defines a playback procedure. In the programmed play order table, as shown in FIG. 25, information track information PINF1, PINF2,... Linked to the track descriptor for each track number is described.
[0168]
In the group information table, information about groups is described as shown in FIG. A group is a set of one or more tracks having a continuous track number, or a set of one or more tracks having a continuous programmed track number. As shown in FIG. 26A, the group information table is described by the group descriptor of each group. In the group descriptor, as shown in FIG. 26B, the track number at which the group starts, the number of the end track, the group name, and the flag are described.
[0169]
As shown in FIG. 27, the track information table describes information about each song. As shown in FIG. 27A, the track information table includes track descriptors for each track (each music piece). As shown in FIG. 27B, each track descriptor includes an encoding method, copyright management information, content decryption key information, pointer information to a part number as an entry at which the music starts, artist name, title name, original Song order information, recording time information, etc. are described. The artist name and title name describe pointer information to the name table, not the name itself. The encoding method indicates a codec method and becomes decoding information.
[0170]
As shown in FIG. 28, the part information table describes a pointer for accessing the actual music position from the part number. As shown in FIG. 28A, the part information table is composed of part descriptors for each part. Parts are all parts of one track (music) or each part obtained by dividing one track. FIG. 28B shows an entry of a part descriptor in the part information table. As shown in FIG. 28B, each part descriptor describes the head address of the part in the audio data file, the end address of the part, and the link destination to the part that follows the part.
[0171]
The addresses used as part number pointer information, name table pointer information, and pointer information indicating the position of the audio file include the byte offset of the file, the part descriptor number, the FAT cluster number, and the physical of the disk used as the recording medium. An address or the like can be used. File byte offset is a specific embodiment of the offset method that can be implemented in the present invention. Here, the part pointer information is an offset value from the start of the audio file, and the value is expressed in a predetermined unit (for example, a block of bytes, bits, and n bits).
[0172]
The name table is a table for representing characters that are names of names. As shown in FIG. 29A, the name table includes a plurality of name slots. Each name slot is called by being linked from each pointer indicating a name. The pointer for calling the name includes the artist name and title name of the track information table, the group name of the group information table, and the like. Each name slot can be called from a plurality. As shown in FIG. 29B, each name slot includes name data that is character information, a name type that is an attribute of the character information, and a link destination. A long name that does not fit in one name slot can be described by being divided into a plurality of name slots. If one name slot does not fit, the link destination to the name slot in which the subsequent name is described is described.
[0173]
In the first example of the audio data management system in the system to which the present invention is applied, as shown in FIG. 30, when the track number to be reproduced is designated by the play order table (FIG. 24), The link destination track descriptor (FIG. 27) is read out, and from this track descriptor, the encoding method, copyright management information, content decryption key information, pointer information to the part number where the music starts, artist name and title A name pointer, original music order information, recording time information, and the like are read out.
[0174]
The part number information read from the track information table is linked to the part information table (FIG. 28). From this part information table, the audio data file of the part position corresponding to the start position of the track (music) is obtained. Accessed. When the data of the part at the position specified in the part information table of the audio data file is accessed, the reproduction of the audio data is started from that position. At this time, decoding is performed based on the encoding method read from the track descriptor of the track information table. If the audio data is encrypted, the key information read from the track descriptor is used.
[0175]
When there is a part that follows the part, a part descriptor is described as the link destination of the part, and the part descriptor is sequentially read according to the link destination. By following the link destination of this part descriptor and playing the audio data of the part at the position specified by the part descriptor on the audio data file, the audio data of the desired track (song) is recorded. Can be played.
[0176]
Also, the name table name slot (FIG. 29) at the position (name pointer information) pointed to by the artist name or title name pointer read from the track information table is called, and from the name slot at that position, Name data is read. The name pointer information may be, for example, a name slot number, a cluster number in the FAT system, or a physical address of the recording medium.
[0177]
As described above, a plurality of name slots in the name table can be referred to. For example, there may be a case where a plurality of music pieces of the same artist are recorded. In this case, as shown in FIG. 31, the same name table is referred to as an artist name from a plurality of track information tables. In the example of FIG. 31, the track descriptor “1”, the track descriptor “2”, and the track descriptor “4” are all music pieces of the same artist “DEF BAND” and refer to the same name slot as the artist name. . Also, the track descriptor “3”, the track descriptor “5”, and the track descriptor “6” are all the music of the artist “GHQ GIRLS” at the same position, and refer to the same name slot as the artist name. Thus, if the name slot of the name table can be referred to from a plurality of pointers, the capacity of the name table can be saved.
[0178]
Along with this, for example, a link to this name table can be used to display information of the same artist name. For example, when it is desired to display a list of songs whose artist name is “DEF BAND”, the track descriptor referring to the address of the name slot of “DEF BAND” is traced. In this example, the track descriptor “1”, the track descriptor “2”, and the track descriptor “4” are obtained by tracing the track descriptor referring to the address of the name slot “DEF BAND”. This makes it possible to display a list of songs whose artist name is “DEF BAND” among the songs stored on the disc. Since a plurality of name tables can be referred to, no link is provided to reversely follow the track information table from the name table.
[0179]
In the case of newly recording audio data, a FAT table provides an unused area that is continuous with a desired number of recording blocks or more, for example, four recording blocks or more. The reason why a continuous area of a desired recording block or more is ensured is that there is no waste in access if audio data is recorded in a continuous area as much as possible.
[0180]
When an area for recording audio data is prepared, one new track descriptor is allocated on the track information table, and a content key for encrypting the audio data is generated. Then, the input audio data is encrypted, and the encrypted audio data is recorded in the prepared unused area. The area where the audio data is recorded is connected to the end of the audio data file on the FAT file system.
[0181]
As new audio data is linked to the audio data file, the linked position information is created, and the newly created audio data position information is recorded in the newly reserved parts description. The Then, key information and part numbers are described in the newly secured track descriptor. Further, if necessary, an artist name, a title name, and the like are described in the name slot, and a pointer linked to the artist name and the title name is described in the name slot in the track descriptor. Then, the number of the track descriptor is registered in the play order table. Also, copyright management information is updated.
[0182]
When reproducing audio data, information corresponding to the designated track number is obtained from the play order table, and the track descriptor of the track to be reproduced is obtained.
[0183]
Key information is acquired from the track descriptor of the track information table, and a part description indicating an area in which entry data is stored is acquired. From the part description, the position on the first audio data file of the part in which the desired audio data is stored is acquired, and the data stored at the position is extracted. Then, the data reproduced from that position is decrypted using the acquired key information, and the audio data is reproduced. If there is a link in the part description, it is specified and linked to the part, and the same procedure is repeated.
[0184]
When a song having a track number “n” on the play order table is changed to a track number “n + m”, the track information in which the track information is described is recorded from the track information TINFn in the play order table. A scripter Dn is obtained. All the values (track descriptor number) of the track information TINFn + 1 to TINFn + m are moved to the previous one. The number of the track descriptor Dn is stored in the track information TINFn + m.
[0185]
When deleting the music piece having the track number “n” in the play order table, the track descriptor Dn in which the information of the track is described is obtained from the track information TINFn in the play order table. All valid track descriptor numbers after the track information entry TINFn + 1 in the play order table are moved to the previous one. Further, since the track “n” is to be deleted, all the track information entries after the track “n” are moved forward by one in the play order table. A part descriptor indicating an area in which an encoding method and a decryption key corresponding to the track are acquired from the track descriptor Dn acquired when the track is erased, and the head music data is stored. The number of Pn is acquired. The audio block in the range specified by the part descriptor Pn is separated from the audio data file on the FAT file system. Further, the track descriptor Dn of the track in the track information table is deleted. Then, the part descriptor is deleted from the part information table, and the part description is released by the file system.
[0186]
For example, in FIG. 32A, parts A, B, and C are connected so far, and part B is deleted from them. Suppose that part A and part B share the same audio block (and share the same FAT cluster), and the FAT chain is continuous. The part C is located immediately after the part B in the audio data file, but when the FAT table is examined, it is assumed that the part C is actually located at a distance.
[0187]
In the case of this example, as shown in FIG. 32B, when part B is deleted, it can be actually removed from the FAT chain (returned to a free area), and the cluster is not shared with the current part. There are two FAT clusters. That is, the audio data file is shortened to 4 audio blocks. The numbers of the audio blocks recorded in part C and the parts after it are all reduced by 4.
[0188]
It should be noted that the deletion can be performed on a part of the track instead of the entire track. When a part of the track is deleted, the remaining track information can be decrypted by using the encoding method and decryption key corresponding to the track acquired from the part descriptor Pn in the track information table. It is.
[0189]
When connecting the track n and the track n + 1 on the play order table, the track descriptor number Dn describing the information of the track is obtained from the track information TINFn in the play order table. Further, the track descriptor number Dm describing the information of the track is obtained from the track information TINFn + 1 in the play order table. All valid TINF values (track descriptor numbers) after TINFn + 1 in the play order table are moved to the previous TINF. By searching the programmed play order table, all the tracks referring to the track descriptor Dm are deleted. A new encryption key is generated, a part descriptor list is extracted from the track descriptor Dn, and the part descriptor list extracted from the track descriptor Dm is connected to the tail of the part descriptor list.
[0190]
When connecting tracks, compare both track descriptors to confirm that there is no problem with copyright management, obtain a parts descriptor from the track descriptor, and if both tracks are connected, there is a provision for fragments. It is necessary to confirm whether it is satisfied with the FAT table. Further, it is necessary to update the pointer to the name table as necessary.
[0191]
When the track n is divided into the track n and the track n + 1, the track descriptor number Dn in which the information of the track is described is acquired from the TINFn in the play order table. From the track information TINFn + 1 in the play order table, the track descriptor number Dm describing the information of the track is acquired. Then, all valid track information TINF values (track descriptor numbers) after TINFn + 1 in the play order table are moved to the next one. A new key is generated for the track descriptor Dn. A list of parts descriptors is extracted from the track descriptor Dn. A new part descriptor is assigned, and the contents of the part descriptor before division are copied there. The part descriptor including the dividing point is shortened immediately before the dividing point. In addition, the link of the part descriptor after the dividing point is cut off. A new part descriptor is set immediately after the dividing point.
[0192]
7. Second example of music data management system
Next, a second example of the audio data management method will be described. FIG. 33 shows a second example of the audio data management system. As shown in FIG. 33, in the management method in the second example, a track index file and a plurality of audio data files are generated on the disc. The track index file and the plurality of audio data files are files managed by the FAT system.
[0193]
As shown in FIG. 34, the audio data file is basically one in which music data of one file is stored. This audio data file has a header. In the header, a title, decryption key information, and copyright management information are recorded, and index information is provided. An index divides music of one track into a plurality of pieces. In the header, the position of each track divided by the index is recorded corresponding to the index number. For example, 255 indexes can be set.
[0194]
The track index file is a file in which various information for managing music data stored in the audio data file is described. As shown in FIG. 35, the track index file includes a play order table, a programmed play order table, a group information table, a track information table, and a name table.
[0195]
The play order table is a table indicating the playback order defined by default. As shown in FIG. 36, the play order table stores information TINF1, TINF2,... Indicating the link destination to the track descriptor (FIG. 39) of the track information table for each track number (song number). The track number is a continuous number starting from “1”, for example.
[0196]
The programmed play order table is a table in which each user defines a playback procedure. In the programmed play order table, as shown in FIG. 37, information track information PINF1, PINF2,... Linked to the track descriptor for each track number is described.
[0197]
In the group information table, information about groups is described as shown in FIG. A group is a set of one or more tracks having a continuous track number, or a set of one or more tracks having a continuous programmed track number. As shown in FIG. 38A, the group information table is described by the group descriptor of each group. In the group descriptor, as shown in FIG. 38B, a track number at which the group starts, an end track number, a group name, and a flag are described.
[0198]
As shown in FIG. 39, the track information table describes information about each song. As shown in FIG. 39A, the track information table includes track descriptors for each track (each song). In each track descriptor, as shown in FIG. 39B, the file pointer, index number, artist name, title name, original song order information, recording time information, etc. of the audio data file containing the song are described. Yes. The artist name and title name are not the name itself but a pointer to the name table.
[0199]
The name table is a table for representing characters that are names of names. As shown in FIG. 40A, the name table includes a plurality of name slots. Each name slot is called by being linked from each pointer indicating a name. The pointer for calling the name includes the artist name and title name of the track information table, the group name of the group information table, and the like. Each name slot can be called from a plurality. Each name slot includes name data, a name type, and a link destination, as shown in FIG. 40B. A long name that does not fit in one name slot can be described by being divided into a plurality of name slots. If one name slot does not fit, the link destination to the name slot in which the subsequent name is described is described.
[0200]
In the second example of the audio data management method, as shown in FIG. 41, when the track number to be reproduced is designated by the play order table (FIG. 36), the track descriptor (FIG. 39) linked to the track information table is designated. ) And the file pointer and index number of the music, the pointer of the artist name and title name, the original music order information, the recording time information, and the like are read from the track descriptor.
[0201]
The audio data file is accessed from the pointer of the music file, and the header information of the audio data file is read. If the audio data is encrypted, the key information read from the header is used. Then, the audio data file is reproduced. At this time, if an index number is designated, the position of the designated index number is detected from the header information, and reproduction is started from the position of the index number.
[0202]
Further, the name slot of the name table at the position indicated by the pointer of the artist name or title name read from the track information table is called, and the name data is read from the name slot at that position.
[0203]
In the case of newly recording audio data, a FAT table provides an unused area that is continuous with a desired number of recording blocks or more, for example, four recording blocks or more.
[0204]
When an area for recording audio data is prepared, one new track descriptor is assigned to the track information table, and a content key for encrypting the audio data is generated. Then, the input audio data is encrypted, and an audio data file is generated.
[0205]
In the newly secured track descriptor, the file pointer and key information of the newly generated audio data file are described. Further, if necessary, an artist name, a title name, and the like are described in the name slot, and a pointer linked to the artist name and the title name is described in the name slot in the track descriptor. Then, the number of the track descriptor is registered in the play order table. Also, copyright management information is updated.
[0206]
When reproducing audio data, information corresponding to the designated track number is obtained from the play order table, and the track descriptor of the track to be reproduced in the track information table is obtained.
[0207]
From the track descriptor, the file pointer and index number of the audio data storing the music data are acquired. Then, the audio data file is accessed, and key information is obtained from the header of the file. Then, the data of the audio data file is decrypted using the acquired key information, and the audio data is reproduced. When the index number is designated, reproduction is started from the position of the designated index number.
[0208]
When the track n is divided into the track n and the track n + 1, the track descriptor number Dn in which the information of the track is described is acquired from the TINFn in the play order table. From the track information TINFn + 1 in the play order table, the track descriptor number Dm describing the information of the track is acquired. Then, all valid track information TINF values (track descriptor numbers) after TINFn + 1 in the play order table are moved to the next one.
[0209]
As shown in FIG. 42, by using the index, the data of one file is divided into a plurality of index areas. The index number and the position of the index area are recorded in the header of the audio track file. In the track descriptor Dn, a file pointer of audio data and an index number are described. A file pointer and an index number of audio data are described in the track descriptor Dm. Thereby, the music M1 of one track of the audio file is apparently divided into the music M11 and M12 of two tracks.
[0210]
When connecting the track n and the track n + 1 on the play order table, the track descriptor number Dn describing the information of the track is obtained from the track information TINFn in the play order table. Further, the track descriptor number Dm describing the information of the track is obtained from the track information TINFn + 1 in the play order table. All valid TINF values (track descriptor numbers) after TINFn + 1 in the play order table are moved to the previous one.
[0211]
Here, when the track n and the track n + 1 are in the same audio data file and are divided by the index, as shown in FIG. 43, the index information in the header can be deleted to connect them. is there. Thereby, the music M21 and M22 of two tracks are connected to the music M23 of one track.
[0212]
If track n is the latter half of one audio data file divided by index and track n + 1 is at the head of another audio data file, the data of track n divided by index as shown in FIG. Is added to the audio data file of the music M32. Then, the header of the audio data file of the track n + 1 is removed, and the audio data of the track n + 1 of the music M41 is connected. Thereby, the music M32 and M41 of two tracks are connected as the music M51 of one track.
[0213]
In order to realize the above processing, a function for converting the audio data by the index into one audio data file by adding a header to the track divided by the index and encrypting it with another encryption key; Except for the header of the audio data file, it has a function of linking to other audio data files.
[0214]
8). Operation when connected to a personal computer
The next generation MD1 and the next generation MD2 employ a FAT system as a data management system in order to have compatibility with a personal computer. Therefore, the next-generation MD1 and next-generation MD2 discs support not only audio data but also data reading and writing generally handled by personal computers.
[0215]
Here, in the disk drive device 1, the audio data is reproduced while being read from the disk 90. Therefore, in consideration of the accessibility of the portable disk drive device 1 in particular, it is preferable that a series of audio data is continuously recorded on the disk. On the other hand, general data writing by a personal computer is performed by appropriately allocating free areas on the disk without considering such continuity.
[0216]
Therefore, in the recording / reproducing apparatus to which the present invention is applied, when the personal computer 100 and the disk drive apparatus 1 are connected by the USB hub 7 and writing is performed from the personal computer 100 to the disk 90 attached to the disk drive apparatus 1. The general data writing is performed under the management of the file system on the personal computer side, and the audio data writing is performed under the management of the file system on the disk drive apparatus 1 side.
[0217]
FIG. 45 is a diagram for explaining that the management authority is moved according to the type of data to be written in a state where the personal computer 100 and the disk drive device 1 are connected by the USB hub 7 (not shown). FIG. 45A shows an example in which general data is transferred from the personal computer 100 to the disk drive device 1 and recorded on the disk 90 attached to the disk drive device 1. In this case, FAT management on the disk 90 is performed by the file system on the personal computer 100 side.
[0218]
It is assumed that the disk 90 is a disk formatted by either the next generation MD1 or the next generation MD2.
[0219]
That is, on the personal computer 100 side, the connected disk drive device 1 looks like a single removable disk managed by the personal computer 100. Therefore, for example, data can be read from and written to the disk 90 mounted on the disk drive device 1 so that the personal computer 100 reads and writes data from and to the flexible disk.
[0220]
Such a file system on the personal computer 100 side can be provided as a function of an OS (Operating System) that is basic software installed in the personal computer 100. As is well known, the OS is recorded as a predetermined program file, for example, in a hard disk drive of the personal computer 100. The program file is read when the personal computer 100 is started and is executed in a predetermined manner, so that each function as an OS can be provided.
[0221]
FIG. 45B shows an example in which audio data is transferred from the personal computer 100 to the disk drive device 1 and recorded on the disk 90 attached to the disk drive device 1. For example, in the personal computer 100, audio data is recorded on a recording medium such as a hard disk drive (hereinafter referred to as HDD) included in the personal computer 100.
[0222]
The personal computer 100 requests ATRAC compression encoding of the audio data and also writes the audio data to the loaded disk 90 and deletes the audio data recorded on the disk 90 from the disk drive device 1. It is assumed that utility software is installed. The utility software further has a function of browsing the track information recorded on the disk 90 by referring to the track index file of the disk 90 mounted on the disk drive device 1. The utility software is recorded as a program file in the HDD of the personal computer 100, for example.
[0223]
As an example, a case where audio data recorded on a recording medium of the personal computer 100 is recorded on a disk 90 attached to the disk drive device 1 will be described. It is assumed that the above-described utility software has been activated in advance.
[0224]
First, the user operates the personal computer 100 to record predetermined audio data (referred to as audio data A) recorded on the HDD onto the disk 90 mounted on the disk drive device 1. Based on this operation, a write request command for requesting recording of the audio data A on the disk 90 is output by the utility software. The write request command is transmitted from the personal computer 100 to the disk drive device 1.
[0225]
Subsequently, audio data A is read from the HDD of the personal computer 100. The read audio data A is subjected to ATRAC compression / encoding processing by the above-described utility software installed in the personal computer 100 and converted into ATRAC compressed data. The audio data A converted into the ATRAC compressed data is transferred from the personal computer 100 to the disk drive device 1.
[0226]
On the disk drive device 1 side, when the write request command transmitted from the personal computer is received, the audio data A converted into the ATRAC compressed data is transferred from the personal computer 100, and the transferred data is audio. It is recognized that data is recorded on the disk 90 as data.
[0227]
In the disk drive device 1, the audio data A transmitted from the personal computer 100 is received from the USB hub 7 and sent to the media drive unit 2 via the USB interface 6 and the memory transfer controller 3. The system controller 9 controls the audio data A to be written to the disk 90 based on the FAT management method of the disk drive device 1 when the audio data A is sent to the media drive unit 2. That is, the audio data A is continuously written in units of recording blocks based on the FAT system of the disk drive device 1 with 4 recording blocks, that is, 64 kbytes × 4 as the minimum recording length.
[0228]
Until data writing to the disk 90 is completed, data, status, and commands are exchanged between the personal computer 100 and the disk drive apparatus 1 using a predetermined protocol. As a result, for example, the data transfer speed is controlled so that the overflow or underflow of the cluster buffer 4 does not occur on the disk drive device 1 side.
[0229]
Examples of commands that can be used on the personal computer 100 side include a delete request command in addition to the write request command described above. This deletion request command is a command for requesting the disk drive apparatus 1 to delete the audio data recorded on the disk 90 mounted on the disk drive apparatus 1.
[0230]
For example, when the personal computer 100 and the disk drive device 1 are connected and the disk 90 is loaded into the disk drive device 1, the track index file on the disk 90 is read by the above-described utility software, and the read data Is transmitted from the disk drive device 1 to the personal computer 100. In the personal computer, based on this data, for example, a list of titles of audio data recorded on the disc 90 can be displayed.
[0231]
When the personal computer 100 tries to delete certain audio data (referred to as audio data B) based on the displayed title list, information indicating the audio data B to be deleted is transmitted to the disk drive device 1 together with the delete request command. Is done. When the disk drive apparatus 1 receives this deletion request command, the requested audio data B is deleted from the disk 90 based on the control of the disk drive apparatus 1 itself.
[0232]
Since deletion of audio data is performed by control based on the FAT system of the disk drive device 1 itself, for example, as described with reference to FIGS. 32A and 32B, in a huge file in which a plurality of audio data is collected as one file It is also possible to perform processing such as deleting audio data with a certain size.
[0233]
9. Memory control method
Next explained is a memory control method according to the first embodiment of the invention. FIG. 46 shows a transfer path of data read / written on the disk 90 in FIG. 17 described above. In FIG. 46, parts common to those in FIG. 17 described above are denoted by the same reference numerals and detailed description thereof is omitted. Further, the USB hub 7 for connecting the personal computer (PC) 100 and the media drive unit 2 for driving the disk 90 are omitted.
[0234]
As already described in the above section “3. Recording Format”, the disk 90 has a recording / reproducing access unit of 64 kB. Therefore, data transfer is performed in units of 64 kB between the disk 90 and the memory transfer controller 3. Here, the cluster unit address of the disk 90 is referred to as LCN (Logical Cluster Number), and the sector unit address is referred to as LSN (Logical Sector Number). The memory transfer controller 3 accesses the disk 90 in units of LCN.
[0235]
On the other hand, data transfer is performed between the PC 100 and the memory transfer controller 3 in units of 2 kB, which is one sector of the FAT system according to this embodiment, via the USB I / F 6. Here, the sector unit address of the FAT system is referred to as FSN (FAT Sector Number).
[0236]
The cluster buffer memory 4 is composed of DRAM (Dynamic Random Access Memory). Hereinafter, the cluster buffer memory 4 is appropriately referred to as DRAM 4. The DRAM 4 also serves as a cache memory for the disk 90. The DRAM 4 is managed as a disk image in cluster units. In the DRAM 4, the memory space is managed every 64 kB, and an address is assigned every 2 kB. The DRAM 4 can read and write every 2 kB based on this address. That is, the DRAM 4 can perform writing and reading in units of FAT sectors (FSN), and can perform reading and writing in units of clusters (LCN) with respect to the disk 90. The address of every 2 kB of the DRAM 4 corresponds to the LSN of the disk 90.
[0237]
Hereinafter, for the sake of convenience, the FAT sector unit area in the DRAM 4 is referred to as a DRAM sector.
[0238]
Further, the above-described FSN and LCN undergo one-to-one address conversion. For example, when the data read from the disk 90 is written to the DRAM 4 and the LCN is assigned to the DRAM 4, a correspondence table that can associate the FSN and the LCN is created. The correspondence table is stored in, for example, a RAM included in the system controller 9.
[0239]
FIG. 47 shows an example of this correspondence table. In FIG. 47, the DRAM address and the LCN address are each represented in hexadecimal notation, and the DRAM address is a value counted up by one for each DRAM sector. LCN is a value counted up for each cluster. One LCN and 32 sector fill bits are associated with 32 DRAM addresses.
[0240]
The sector fill bit indicates in which DRAM sector in the LCN valid data is written. That is, data written to the disk 90 is once buffered in the DRAM 4. As described above, the DRAM 4 can be accessed in units of FAT sectors. For example, when non-continuous data is supplied from the PC 100, as shown in FIG. It is conceivable that data is written in a DRAM sector arbitrarily allocated on the PC 100 side. Therefore, a DRAM sector (indicated by hatching in FIG. 48) in which valid data is written is set to, for example, “1”, and a DRAM sector in which no data is written is set to “0” to form a 32-bit sector fill bit.
[0241]
The disk 90 is accessed by designating the FSN and data length (LENG) from the PC 100. When (FSN, LENG) is converted by a predetermined conversion formula, LCN and sector fill bit are obtained. For example, it is assumed that (FSN, LENG) designated by access from the PC 100 is converted, and LCN = 104h and sector fill bit = 7 are obtained. In this case, the cluster of LCN = 104h is reproduced from the disk 90 and written to the DRAM 4, and the data of the DRAM sector corresponding to the seventh sector fill bit is taken out from the DRAM 4.
[0242]
FIG. 49 shows a sequence chart as an example when predetermined data on the disk 90 is read from the PC 100. In the figure, the USB task is data transfer processing by the USB I / F 6. The cache task is control of writing and reading with respect to the DRAM 4 by the memory transfer controller 3. The drive task is a recording / reproduction control of the disk 90 by the media drive unit 2.
[0243]
The PC 100 designates FSN and LENG for the disk 90, and issues a read request for requesting data reproduction (SEQ100). This read request is passed to the cache task via the USB task (SEQ101). The cache task converts the received (FSN, LENG) by a predetermined conversion formula to obtain the LCN and sector fill bit, and assigns an address to the DRAM 4 (step S300). The DRAM address, LCN, and sector fill bit are registered in the correspondence table described above.
[0244]
When address assignment to the DRAM 4 is performed, next, LCN, LSN (sector fill bit) and LENG are designated from the cache task to the drive task, and a read request for requesting data reproduction from the disk 90 is issued (SEQ102). ). The drive task reads data from the disk 90 in units of LCN based on the received read request (step S301). The read data is sequentially transferred to the cache task and written into the DRAM 4. When data reading from the address specified by the read request is completed, a read completion notification is passed from the drive task to the cache task together with the LCN from which data was read (SEQ103).
[0245]
Since data is read from the disk 90 in units of LCN, that is, every 64 kB, data is written to all DRAM addresses in the 64 kB management area of the DRAM 4. Therefore, all the sector fill bits in the management area in which data is written are set to “1” (step S302).
[0246]
When the reproduction data is written in the DRAM 4, the cache task notifies which address in the DRAM 4 the data requested from the PC 100 is written based on the contents registered in the correspondence table in the above-described step S300 (SEQ104). ). The USB task that has received this notification reads data from the DRAM 4 for each DRAM sector and stores it in the buffer memory of the USB I / F 6. The necessary 2 kB is copied from the buffer to the PC 100, and the data read from the disk 90 is passed to the PC 100 (SEQ106).
[0247]
Here, consider the case of handling continuous data such as audio data. When handling continuous data, it is convenient to use the DRAM 4 as a ring buffer for accessing addresses cyclically. In the ring buffer, the address is continuously written to the data continuously supplied, and when the writing is performed up to the maximum address, the old data is overwritten from the lowest address as if the addresses are continuous in a ring shape. However, data writing is continued.
[0248]
On the other hand, since the disk 90 can be accessed only in cluster units, even when data is required from a predetermined LSN in the cluster, it is necessary to read the data of the entire cluster represented by the LCN including the LSN. When the read data is written to the DRAM 4, the data is written in 64 kB management units in the DRAM 4 in this cluster unit.
[0249]
As described above, the DRAM 4 can read and write data in a fractional unit of 2 kB with respect to 64 kB. On the other hand, the disk 90 cannot be accessed in cluster units as described above. Therefore, as shown in an example in FIG. 50, when data read from the disk 90 is written to the DRAM 4, the fractional part of 64 kB is overwritten with the data read from the disk 90. There is a fear.
[0250]
In the first embodiment of the present invention, in order to solve this problem, a work DRAM is used, and data read from the disk 90 in units of clusters is temporarily written into the work DRAM. The data written in the work DRAM is accessed in the access unit (DRAM sector unit) of the work DRAM, the necessary data is copied to the DRAM 4, and the data reading from the disk 90 in the sector unit is realized. The work DRAM may be provided in the DRAM 4 as a separate area from the management area for every 64 kB.
[0251]
FIG. 51 shows a procedure for copying between DRAMs according to the first embodiment. An example of processing for writing data on the disk 90 indicated by hatching in FIG. 51A to the position indicated by hatching in the DRAM 4 shown in FIG. 51C will be described. FIG. 51B shows data written to the work DRAM. Here, it is assumed that this processing is performed by the FAT system of the disk drive device 1 itself. Data access processing by the FAT system of the disk drive device 1 itself is called a file task.
[0252]
First, FSN and LENG are specified by the file task, and a read request is issued to the cache task. Based on this read request, FSN and LCN conversion processing, correspondence table creation / registration, address assignment processing for the DRAM 4 and the like are performed in the same manner as described above with reference to FIG. Then, the cache task issues a request to read the first cluster among the data requested to be read from the file task to the drive task. Data read based on this request is written to the work DRAM (SEQ200). The cache task refers to the correspondence table based on the FSN and LENG passed from the file task, and copies necessary data among the data written in the work DRAM to the DRAM 4 (SEQ201).
[0253]
When copying is completed for the first cluster, data excluding the last cluster is read from the disk 90 in cluster units and written to the DRAM 4 (SEQ202). In the example of FIG. 51, data for two clusters is read and written in the DRAM 4. The last cluster is read from the disk 90 and written to the work DRAM (SEQ203). In the same manner as SEQ201 described above, necessary data among the data of the last one cluster written in the work DRAM is copied to the DRAM 4 (SEQ204).
[0254]
Next, a second embodiment of the present invention will be described. In the second embodiment, when data is read from the disk 90 and written to the DRAM 4, a mask is set for an unnecessary data portion so that the data in that portion is not written to the DRAM 4.
[0255]
This will be described with reference to FIG. A description will be given of the case where the data in the hatched portion recorded on the disk 90 shown in FIG. 52B is written in the hatched portion of the DRAM 4 as shown in FIG. 52A. When writing data read from the disk 90 to the DRAM 4, a mask is set for each DRAM sector of the DRAM 4. Note that the reading of data from the disk 90 and the transfer of the read data are performed in cluster units.
[0256]
The sector fill bit described above can be used as this mask. For example, when one cluster of data is read from the disk 90 and written to the DRAM 4, all the 32 sector fill bits are normally set to “1”. Based on the FSN and LENG first passed from the file task, for example, the sector fill bit corresponding to the FAT sector requested to be accessed is set to “1” and the others are set to “0”.
[0257]
When the data read from the disk 90 is written to the DRAM 4, the memory transfer controller 3 does not write data to the FAT sector in which the sector fill bit is “1”, and the FAT in which the sector fill bit is “0”. Control to write data only to sectors. By setting the sector mask in this way, data can be written only in the shaded area in FIG. 52A, and data in other parts of the DRAM 4 is not destroyed.
[0258]
In the first embodiment described above, (1) read first cluster and copy between DRAMs, (2) intermediate cluster read, (3) read last cluster and copy between DRAMs. Cluster read processing was required. On the other hand, in the second embodiment, the processing is completed with one cluster read.
[0259]
The sector transfer function can be provided to the memory transfer controller 3. For example, the memory transfer controller 3 includes a single IC (Integrated Circuit), and can switch whether or not to transfer data read from the disk 90 in units of sectors. The setting for switching in units of sectors is performed, for example, when the system controller 9 sets a sector fill bit for the memory transfer controller 3 before starting data transfer.
[0260]
By configuring the memory transfer controller 3 and the system controller 9 in this way, when the data read from the disk 90 is written into the DRAM 4, the FAT sector in which the sector fill bit is set to “1” by the memory transfer controller 3. It is possible to control to write data in the FAT sector in which the sector fill bit is set to “0” without writing data.
[0261]
Also, by using this sector mask, data is transferred and written to only one DRAM sector of the data read in units of clusters from the disk 90 to the DRAM 4 in which no valid data is written. Processing is also possible.
[0262]
Next explained is the third embodiment of the invention. The third embodiment is an example in which the DRAM 4 is effectively used as a cache memory of the disk 90. This will be described with reference to FIGS. 53 and 54. FIG. 53 shows a correspondence relationship between a file task, a DRAM address, and an example address of the disk 90. FIG. 54 is a sequence chart showing an example of processing according to the third embodiment.
[0263]
In FIG. 53, the FSN of the file task, the DRAM address, and the LCN of the drive (disk 90) are in hexadecimal notation and correspond to each other. For example, DRAM address “500h” corresponds to LCN “100h”, and data read from the cluster indicated by LCN “100h” is written to 64 kB consisting of addresses “500h” to “519h” of DRAM4. It is. In FIG. 54, “N_FSN” indicates the number of FSNs, and “N_LCN” indicates the number of LCNs.
[0264]
Prior to the processing of FIG. 54, as an example, a read request is issued to the cache task so that 96 kB data from FSN = “2000h” to “2029h” is read from the disk 90 by the file task in the disk drive device 1. Suppose that is issued. That is, data to be written to DRAM addresses “500h” to “529h” is requested from the file task to the cache task. The cache task registers a correspondence table based on this read request, and issues a read request to the drive task so as to read data from the LCN (“100h” to “101h”) corresponding to the DRAM address. For example, the LCN at this time is stored in the cache task by the correspondence table.
[0265]
In the drive task, data is read from the disk 90 based on the passed read request, and is passed to the cache task. Since the disk 90 can be accessed only in cluster units, the data of LCN = “100h” to “101h” is read and written to the DRAM addresses “500h” to “539h”. The file task reads data from the DRAM addresses “500h” to “529h”.
[0266]
Here, consider a case where a read request is issued by the file task so that 40 FSN data is read from the disk 90 from FSN = “2030h”. Referring to FIG. 54, (FSN, N_FSN) = (2030h, 40) is passed from the file task to the cache task, and a cache read request is issued (SEQ300). This corresponds to “530h” to “569h” in the DRAM address.
[0267]
In the cache task, the FSN is converted to LCN based on this request and registered in the correspondence table, and it is checked whether or not it overlaps with the LCN stored at the time of the previous read request. In this example, the LCN stored at the time of the previous read request is “100h” to “101h”, whereas the LCN by the current read request is “101h” to “103h”, Based on this, it can be determined that the LCN “101h” overlaps with the previous time. Thus, if there is an LCN that overlaps with the previous time, the cache task rounds up the LCN in the read request issued to the drive task (step S310). That is, in the example of FIG. 53, data reading is started from LCN = “102h” after one cluster of requested LCN = “101h”, and data is read for two clusters until LCN = “103h”. A read request is issued to the drive task (SEQ301).
[0268]
Based on this request, the drive task reads data from the disk (step S311), and the read data is written in the corresponding addresses “540h” to “579h” of the DRAM 4. That is, the data up to the DRAM address “569h” requested from the file task and the data from the DRAM addresses “570h” to “579h” not requested this time are written in the DRAM 4.
[0269]
When the drive task finishes reading data from the disk 90, the drive task notifies the cache task (SEQ302). The cache task that has received this notification notifies the file task that the requested data (FSN, N_FSN) = (2030h, 40) has been written in the DRAM 4 (SEQ303).
[0270]
In the third embodiment, the sector mask described in the second embodiment can also be used. By setting the sector mask and reading from the disk 90, it is possible to prevent unnecessary data from accumulating in the DRAM 4. On the other hand, when the sector mask is applied in the third embodiment, at the time of drive read, for example, a mask is first set to DRAM addresses “500h” to “529h”, and data of LCN = “100h” to “101h” is read from the disk 90. Read and write to the DRAM 4, then set the mask from the DRAM address “570h” to “579h” and read the data of LCN = “102h” to “103h” from the disk 90. Necessary.
[0271]
The method using the sector mask and the method not using the sector mask can be switched and executed according to the application, the application of the disk drive device 1 and the like. In this way, an optimal memory control method can be realized for each application and application.
[0272]
In the above description, the present invention has been described as applied to a reproducing apparatus that reproduces data from a disc-shaped recording medium, but this is not limited to this example. That is, the present invention is also applicable to a reproducing apparatus that reproduces data from another recording medium or storage medium that is accessed in a data unit larger than the sector of the buffer memory. For example, the present invention can be applied to a reproducing apparatus using a semiconductor memory such as a flash memory as a recording medium or a storage medium.
[0273]
Here, to show an example of the correspondence relationship with the claims, in claim 1, the playback means corresponds to, for example, the media drive unit 2 and the system controller 9. The memory corresponds to, for example, a cluster buffer memory (DRAM) 4. The correspondence table is a table whose example is shown in FIG. 47, and is stored in, for example, a RAM included in the system controller 9. The memory control means corresponds to, for example, the memory transfer controller 3 and the system controller 9. The fill information corresponds to a sector fill bit, for example.
[0274]
【The invention's effect】
As described above, according to the present invention, when data is read from a disk that is accessed in cluster units, and the data is written to a memory that is accessed in sector units having a size smaller than the cluster, the data is read from the disk in cluster units. Since the data read and read is indicated in the sector unit as valid / invalid, only the necessary part of the data read from the disk can be selectively written to the memory. This is advantageous in that the reading process can be performed at high speed.
[0275]
In addition, since only a necessary portion of the data read from the disk can be selectively written into the memory in units of sectors, there is an effect that the memory can be used efficiently.
[0276]
In addition, since only the necessary part of the data read from the disk can be selectively written into the memory in units of sectors, conventionally when reading from the disk, the reading from the disk is divided into multiple times when the memory is used as a ring buffer. Thus, the processing that has to be performed can be completed by a single read operation, so that the processing speed is increased, the number of disk accesses is reduced, and the power consumption can be reduced. Therefore, in a battery-driven disk drive device or the like, there is an effect that the duration of the battery becomes longer.
[0277]
Furthermore, since the memory is managed in units of sectors and is managed corresponding to the cluster based on the disk image, there is an effect that cache processing at the time of disk access can be easily performed.
[Brief description of the drawings]
BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a diagram used for explaining a disk having specifications of a next generation MD1 system.
FIG. 2 is a diagram used for explaining a recording area of a disc having a specification of a next generation MD1 system.
FIG. 3 is a diagram used for explaining a disk having specifications of a next-generation MD2 system.
FIG. 4 is a diagram used for explaining a recording area of a disc of the specification of the next generation MD2 system.
FIG. 5 is a schematic diagram schematically illustrating a format of an example of a UID.
FIG. 6 is a diagram used for explaining error correction encoding processing of the next generation MD1 and the next generation MD2.
FIG. 7 is a diagram used for explaining error correction encoding processing of the next generation MD1 and the next generation MD2.
FIG. 8 is a diagram used for explaining error correction encoding processing of the next generation MD1 and the next generation MD2.
FIG. 9 is a perspective view used for explaining generation of an address signal using wobble.
FIG. 10 is a diagram used for explaining ADIP signals of the current MD system and the next generation MD1 system.
FIG. 11 is a diagram used for explaining ADIP signals of the current MD system and the next generation MD1 system.
FIG. 12 is a diagram used for explaining an ADIP signal of the next generation MD2 system.
FIG. 13 is a diagram used for explaining an ADIP signal of the next generation MD2 system.
FIG. 14 is a diagram illustrating a relationship between an ADIP signal and a frame in the current MD system and the next generation MD1 system.
FIG. 15 is a diagram illustrating a relationship between an ADIP signal and a frame in the next generation MD1 system.
FIG. 16 is a diagram used for explaining control signals in the next-generation MD2 system;
FIG. 17 is a block diagram of a disk drive device.
FIG. 18 is a block diagram illustrating a configuration of a media drive unit.
FIG. 19 is a flowchart showing an example of initialization processing of a disc by the next generation MD1.
FIG. 20 is a flowchart showing an example of initialization processing of a disc by the next generation MD2.
FIG. 21 is a diagram used for describing a first example of an audio data management method;
FIG. 22 is a diagram used for explaining an audio data file according to a first example of an audio data management method;
FIG. 23 is a diagram used for describing a track index file according to a first example of an audio data management method;
FIG. 24 is a diagram used for describing a play order table according to a first example of an audio data management method;
FIG. 25 is a diagram used for describing a programmed play order table according to a first example of an audio data management method;
FIG. 26 is a diagram used for describing a group information table according to a first example of an audio data management method;
FIG. 27 is a diagram used for describing a track information table according to a first example of an audio data management method;
FIG. 28 is a diagram used for describing a part information table according to a first example of an audio data management method;
FIG. 29 is a diagram used for describing a name table according to a first example of an audio data management method;
FIG. 30 is a diagram for describing an example process according to a first example of an audio data management method;
FIG. 31 is a diagram for explaining that a plurality of name slots in the name table can be referred to;
FIG. 32 is a diagram used for describing processing for deleting a part from an audio data file in the first example of the audio data management method;
FIG. 33 is a diagram used for describing a second example of the audio data management method;
FIG. 34 is a diagram illustrating the structure of an audio data file according to a second example of the audio data management method;
FIG. 35 is a diagram used for describing a track index file according to a second example of the audio data management method;
FIG. 36 is a diagram used for describing a play order table according to the second example of the audio data management method;
FIG. 37 is a diagram used for describing a programmed play order table according to the second example of the audio data management method;
FIG. 38 is a diagram used for describing a group information table according to the second example of the audio data management method;
FIG. 39 is a diagram used for describing a track information table according to a second example of the audio data management method;
FIG. 40 is a diagram used for describing a name table according to a second example of an audio data management method;
FIG. 41 is a diagram for describing an example process according to a second example of the audio data management method;
FIG. 42 is a diagram for explaining that data of one file is divided into a plurality of index areas by an index in the second example of the audio data management method;
[Fig. 43] Fig. 43 is a diagram used for describing connection of tracks in the second example of the audio data management method.
[Fig. 44] Fig. 44 is a diagram illustrating a second example of an audio data management method used for describing connection of tracks according to another method.
FIG. 45 is a diagram for explaining that the management authority is moved according to the type of data to be written in a state in which the personal computer and the disk drive device are connected.
FIG. 46 is a block diagram showing a transfer path of data read / written on a disk.
FIG. 47 is a schematic diagram illustrating a configuration of an example of a correspondence table capable of associating an FSN and an LCN.
FIG. 48 is a diagram for explaining sector fill bits.
FIG. 49 is a sequence chart of an example when predetermined data on a disk is read from a PC.
FIG. 50 is a diagram for explaining that necessary data on a DRAM is overwritten with data read from a disk;
FIG. 51 is a schematic diagram showing a procedure for copying between DRAMs according to the first embodiment of the invention;
FIG. 52 is a diagram for explaining data reading using a sector mask according to the second embodiment of the invention;
FIG. 53 is a schematic diagram illustrating a correspondence relationship between a file task, a DRAM address, and an address of an example of a disk.
FIG. 54 is a sequence chart showing an example of processing according to the third embodiment of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Disk drive apparatus, 2 ... Media drive part, 3 ... Memory transfer controller, 4 ... Cluster buffer memory, 5 ... Auxiliary memory, 6, 8 ... USB interface, 7 USB hub, 10 ... audio processing unit, 12 ... RS-LDC encoder, 13 ... 1-7pp modulation unit, 14 ... ACIRC encoder, 15 ... EFM modulation unit, 16 ... Selector, 17 ... Magnetic head driver, 18 ... Magnetic head, 19 ... Optical head, 22 ... 1-7 Demodulator, 23 ... RS-LDC decoder, 23 ... EFM modulation , 24 ... ACIRC decoder, 26 ... selector, 30 ... ADIP demodulator, 32,33 ... address decoder, 50 ... switch, 90 ... disc 100 ... personal computer

Claims (9)

In a reproducing apparatus for reproducing data from a recording medium for reproducing data in a first data unit,
Reproducing means for reproducing data in a first data unit from a recording medium;
A memory space managed in a unit corresponding to the first data unit and accessible in a second data unit smaller than the first data unit;
Fill information indicating, in the second data unit, whether the data is valid for the address on the memory, the first data unit of the recording medium, and the memory space management unit corresponding to the address of the memory A correspondence table that associates
And a memory control unit for writing the data reproduced by the reproducing unit into the memory based on the fill information. The playback device according to claim 1,
The reproducing apparatus according to claim 1, wherein the second data unit is a sector, and the first data unit is a cluster including a plurality of the second data units. The playback device according to claim 1,
A data read request to the recording medium is made in the second data unit, and the data in the first data unit obtained based on the correspondence table in response to the data read request is reproduced by the reproducing means and the memory control is performed. The data is written in the memory by the means, and the data written in the memory can be read in the second data unit based on the fill information associated with the first data unit by the correspondence table. A playback device. The playback device according to claim 1,
The memory control means controls to temporarily hold the data reproduced by the reproducing means in the first data unit and to write the held data to the memory based on the fill information. Playback device. The playback device according to claim 1,
The reproduction apparatus according to claim 1, wherein the memory control means performs control so as not to write data to an address on the memory where the data is shown to be valid based on the fill information. The playback device according to claim 1,
The playback apparatus according to claim 1, wherein the memory control means controls to write data of one second data unit to the memory in which the valid data is not written based on the fill information. The playback device according to claim 1,
The address on the memory is used cyclically, and the data is data written continuously in an address,
When the recording medium is requested to read data in the second data unit, the requested data is already at the address on the memory corresponding to the second data unit specified in the request. If written, the reproduction means performs the reproduction from the first data unit one first data unit after the first data unit corresponding to the second data unit. A playback device. The playback device according to claim 1,
The address on the memory is used cyclically, and the data is data written continuously in an address,
A data read request for the recording medium is made in the second data unit, and the data in the first data unit obtained based on the correspondence table in response to the data read request is reproduced by the reproducing means and the memory control is performed. Means to write to the memory,
A first mode in which data written in the memory is read in the second data unit based on the fill information associated with the first data unit according to the correspondence table;
If the data requested by the data read request has already been written to the address on the memory corresponding to the second data unit designated by the request, the first data unit corresponding to the second data unit corresponds to the first data unit. A second mode in which the reproduction by the reproduction means is performed from a first data unit one data data unit after the first data unit;
A playback apparatus characterized in that the first mode and the second mode can be switched and executed. In a reproducing method for reproducing data from a recording medium for reproducing data in a first data unit,
A reproduction step of reproducing data in a first data unit from the recording medium;
A memory space is managed in a unit corresponding to the first data unit, an address on a memory accessible in a second data unit smaller than the first data unit, a first data unit of the recording medium, and Associating fill information indicating in the second data unit whether data is valid for the memory space management unit corresponding to the address of the memory;
And a memory control step of writing the data reproduced in the reproduction step into the memory based on the fill information.

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