JP3994539B2 - Playback device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a reproducing apparatus for reading data by rotating a loaded disc at a constant angular velocity when reproducing a disc on which data is recorded so that the linear velocity is constant.
[0002]
[Prior art]
Recently, for example, discs have become popular as recording media.
Many of these disks are desirably recorded at the same density as the density on the inner circumferential side over the entire recording area of the disk in order to reduce the size of the disk or increase the recording capacity.
In the disk drive device, the data recorded on the disk is read while moving the pickup as the data reading means in the radial direction of the disk. In this case, the data recorded on the inner circumference side is reproduced or CLV (Constant Linear Velocity) control is employed in reproducing the data recorded on the outer peripheral side, that is, driving the spindle motor in accordance with the position of the pickup and controlling the number of revolutions of the disk. Accordingly, for example, the linear velocity is set to 1.2 to 1.4 m / s in a CD (Compact Disc), for example, and the linear velocity is made constant in one disc. In this case, for example, when playback is performed at 1 × speed, the speed is about 600 rpm when the pickup is on the inner circumference side of the disk, and about 200 rpm when the pickup is on the outer circumference side of the disk.
[0003]
[Problems to be solved by the invention]
By the way, with the spread of disk media, it is desired to shorten the access time of the disk drive device. That is, the access time is shortened by increasing the number of revolutions of the disk and shortening the rotation waiting time. However, in the CLV control, it is necessary to change the number of rotations of the disk according to the pickup position in the radial direction of the disk, which places a burden on the rotation control process.
[0004]
Therefore, in order to improve the access time, CAV (Constant Angular Velocity) control is mainly used to keep the disk rotation speed constant.
However, when data is read by CAV control with respect to a disk created assuming CLV control, the transfer rate differs between the inner and outer peripheral sides of the disk. In this case, if the capacity of the data recorded on the disk is large and recording is performed from the inner circumference side to the vicinity of the outer circumference, data transfer is performed at the maximum transfer rate of the disk drive device on the outer circumference side of the disk. Can be done. However, if the data recording capacity is relatively small, for example, when a disc on which recording has been performed only up to about the middle point between the inner periphery and the outer periphery is reproduced, the data can be stored at a position where the maximum transfer rate can be realized. Recording is not done.
That is, when reading data from a disk having a relatively small data capacity, there is a problem that the transfer capability of the disk drive device can be maximized.
[0005]
[Means for Solving the Problems]
  In order to solve such a problem, the present invention provides a reproducing apparatus capable of reproducing a disc, a disc rotating means for rotating the loaded disc, a discriminating means for discriminating the type of the disc, The logical block address of the data recorded on the outermost periphery of the data area where the data is recorded,in frontDetect from the management information area of the diskDetection meansAnd saidDetection meansDetected inDetection resultControl means for controlling the disk rotation means based on the determination result of the determination means, and for controlling the disk to rotate at a predetermined rotational speed, and determining the type of the disk by the determination means. After the determination, the determination result and the recording method of the data on the discA detection result detected by the detection means;On the basis of the,Data capacity of the diskIs detected, and the detected data capacity is compared with a predetermined determination capacity, whereby the rotation speed of the disc is set to constitute a playback device.
  Further, the control means controls the disk rotation means so that the data recorded on the outermost periphery can be read out at the maximum transfer rate in the reproducing apparatus based on the data capacity detected by the capacity detection means. Try to control.
[0006]
  And a disc structure identifying means capable of identifying the structure of the recording surface of the disc from the management information area of the disc, wherein the disc has a recording surface of a two-layer structure by the disc structure identifying means, and When identifying that the recording direction of the first recording surface formed in the first layer and the second recording surface formed in the second layer are the same direction as the radial direction of the disc, The capacity detecting means compares the logical block address of the data recorded on the outermost circumference on the first and second recording surfaces, and uses the logical block address closer to the outer circumference of the disk as the data capacity. To.
  Further, it further comprises disk diameter information detecting means for detecting the diameter information of the disk from the management information area of the disk, and the rotational speed of the disk is set based on the diameter information detected by the disk diameter information detecting means. So that
  The control means is detected by the disk diameter information detection means.SaidBased on the diameter information, the disk rotating means is controlled so that data recorded on the outermost periphery can be read out at the maximum transfer rate in the reproducing apparatus.
[0007]
  According to the present invention, the data capacity of the diskAnd disc type andTherefore, the maximum transfer rate that can be realized in the signal processing of the playback apparatus can be obtained even for a disk with a small data capacity. . Also the diameter of the discAnd disc type andTherefore, the maximum transfer rate that can be realized in the signal processing of the reproducing apparatus can be obtained even for a disk having a small data diameter. .
[0008]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of a playback apparatus according to the present invention will be described below in the following order.
1. Configuration of playback device
2. CD TOC and subcode
3. Composition of DVD lead-in area
4). Disc (DVD) configuration
5. Rotation speed setting
[0009]
1. Configuration of playback device
As the optical disk loaded in the playback apparatus (disk drive apparatus) of the present embodiment, for example, a DVD (Digital Versatile Disc) or a CD-type disk such as a CD-ROM can be considered. Of course, the present invention can also be applied to a reproducing apparatus compatible with other types of optical disks.
[0010]
FIG. 1 is a block diagram of the main part of the disk drive device 70 of this example.
For example, data is recorded on the disk 90 by the CLV method. When the disk 90 is loaded in the disk drive device 70, the disk 90 is loaded on the turntable 7, and is driven to rotate, for example, at a constant angular velocity (CAV) by the spindle motor 6 during reproduction operation. . The pickup 1 reads data recorded on the disk 90 in the form of embossed pits or phase change pits. In this example, the CAV method is described, but it can also be rotationally driven by a constant linear velocity (CLV) method.
[0011]
In the pickup 1, a laser diode 4 serving as a laser light source, a photodetector 5 for detecting reflected light, an objective lens 2 serving as an output end of the laser light, and a laser recording light are irradiated onto the disk recording surface via the objective lens 2. In addition, an optical system for guiding the reflected light to the photodetector 5 is formed.
The objective lens 2 is held by a biaxial mechanism 3 so as to be movable in the tracking direction and the focus direction.
The entire pickup 1 can be moved in the radial direction of the disk by a thread mechanism 8.
[0012]
Reflected light information from the disk 90 is detected by the photodetector 5, converted into an electrical signal corresponding to the amount of received light, and supplied to the RF amplifier 9.
The RF amplifier 9 includes a current-voltage conversion circuit, a matrix calculation / amplification circuit, and the like corresponding to output currents from a plurality of light receiving elements as the photodetector 5, and generates necessary signals by matrix calculation processing. For example, an RF signal as reproduction data, a focus error signal FE for servo control, a tracking error signal TE, and the like are generated.
The reproduction RF signal output from the RF amplifier 9 is supplied to the binarization circuit 11, and the focus error signal FE and tracking error signal TE are supplied to the servo processor 14.
[0013]
The reproduction RF signal obtained by the RF amplifier 9 is binarized by the binarization circuit 11 so that a so-called EFM signal (8-14 modulation signal; in the case of CD) or EFM + signal (8-16 modulation signal; DVD) And is supplied to the decoder 12. The decoder 12 performs EFM demodulation, error correction processing, and the like, and reproduces information read from the disk 90 by performing CD-ROM decoding or MPEG decoding as necessary.
[0014]
The decoder 12 accumulates the EFM demodulated data in the cache memory 20 as a data buffer, and performs error correction processing and the like on the cache memory 20. Then, buffering to the cache memory 20 is completed in a state where the error is corrected and appropriate reproduction data is obtained.
As playback output from the disk drive device 70, the data buffered in the cache memory 20 is read out and transferred out.
[0015]
The interface unit 13 is connected to an external host computer 80 and communicates reproduction data and read commands with the host computer 80.
That is, the reproduction data stored in the cache memory 20 is transferred and output to the host computer 80 via the interface unit 13.
A read command and other signals from the host computer 80 are supplied to the system controller 10 via the interface unit 13.
[0016]
The servo processor 14 generates various servo drive signals for focus, tracking, thread, and spindle from the focus error signal FE and tracking error signal TE from the RF amplifier 9 and the spindle error signal SPE from the decoder 12 or the system controller 10. Execute servo operation.
That is, a focus drive signal and a tracking drive signal are generated according to the focus error signal FE and the tracking error signal TE and supplied to the biaxial driver 16. The biaxial driver 16 drives the focus coil and tracking coil of the biaxial mechanism 3 in the pickup 1. Thus, a tracking servo loop and a focus servo loop are formed by the pickup 1, the RF amplifier 9, the servo processor 14, the biaxial driver 16, and the biaxial mechanism 3.
[0017]
The servo processor 14 supplies the spindle motor driver 17 with a spindle drive signal generated according to the spindle error signal SPE. The spindle motor driver 17 applies, for example, a three-phase drive signal to the spindle motor 6 according to the spindle drive signal, and causes the spindle motor 6 to perform CAV rotation. In the case of the CAV method, the spindle error signal SPE can be obtained by comparing an FG pulse described later with reference speed information.
Further, the servo processor 14 generates a spindle drive signal in response to the spindle kick / brake control signal from the system controller 10, and causes the spindle motor driver 17 to start and stop the spindle motor 6.
[0018]
The rotation speed of the spindle motor 6 can be set to high speed rotation such as n × 2 times speed, n × 4 times speed, n × 8 times speed when the normal speed is n times speed. Such speed setting is realized by the system controller 10 variably setting reference speed information to be compared with the spindle error signal SPE.
In the present invention, the determination reference capacity for selecting the reference speed information and setting the disk rotation speed is recorded in the memory 22. As will be described later, this determination reference capacity is compared with the data capacity recorded on the disk 90, and required reference speed information is selected based on the comparison result. The disk rotation speed set based on the comparison result is a speed at which the maximum data transfer rate in the disk drive device 70 can be obtained.
[0019]
The FG 21 generates a frequency pulse (FG) pulse corresponding to the rotation speed of the spindle motor 6 and supplies it to the servo processor 14. For example, six FG pulses are generated per one rotation of the spindle motor 6.
[0020]
Note that the system controller 10 can set various linear speeds as the CLV rotation of the spindle motor 6.
For example, the decoder 12 generates a reproduction clock synchronized with the EFM signal for use in the decoding process, and the current rotation speed information can be obtained from this reproduction clock. The system controller 10 or the decoder 12 generates a spindle error signal SPE for the CLV servo by comparing the current rotational speed information and the reference speed information. Therefore, the system controller 11 can change the linear velocity as the CLV rotation by switching the value as the reference velocity information. For example, linear speeds such as 4 × speed and 8 × speed can be realized based on a certain normal linear speed. As a result, the data transfer rate can be increased.
[0021]
The servo processor 14 generates a thread drive signal based on, for example, a thread error signal obtained as a low frequency component of the tracking error signal TE, access execution control from the system controller 10, and supplies the thread drive signal to the thread driver 15. The thread driver 15 drives the thread mechanism 8 according to the thread drive signal. Although not shown in the figure, the thread mechanism 8 has a mechanism including a main shaft that holds the pickup 1, a thread motor, a transmission gear, and the like, and the thread driver 15 drives the thread motor 8 in accordance with a thread drive signal. The required slide movement is performed.
[0022]
The laser diode 4 in the pickup 1 is driven to emit laser light by a laser driver 18.
When the system controller 10 executes a reproducing operation on the disk 90, the system controller 10 sets the laser power control value in the auto power control circuit 19, and the auto power control circuit 19 performs laser output according to the set laser power value. The laser driver 18 is controlled as shown in FIG.
[0023]
Various operations such as servo, decoding, and encoding as described above are controlled by a system controller 10 formed by a microcomputer.
The system controller 10 executes various processes according to commands from the host computer 80.
For example, when a read command requesting transfer of certain data recorded on the disk 90 is supplied from the host computer 80, seek operation control is first performed for the instructed address. That is, a command is issued to the servo processor 14 to cause the pickup 1 to access the address specified by the seek command.
Thereafter, operation control necessary for transferring the data in the designated data section to the host computer 80 is performed. That is, data requested from the disk 90 is read / decoded / buffered and the requested data is transferred.
[0024]
A read command from the host computer 80, that is, a transfer request, has a request start address that is the first address of the requested data section and a request data length (data length) that is a section length from the first address.
For example, a transfer request of request start address = N and request data length = 3 means a data transfer request of three sectors LBA “N” to LBA “N + 2”. LBA is a logical block address (LOGICAL BLOCK ADDRESS) and is an address given to a data sector of the disk 90.
[0025]
By the way, in the present invention, the rotational speed of the disk 90 is set according to the data capacity of the disk 90. For example, when the disk 90 is a CD, the data capacity can be detected based on the TOC of the lead-in area and the absolute time address in the subcode.
When the disk 90 is a DVD, the last sector number recorded in the logical format information in the lead-in area is information corresponding to the data capacity.
Hereinafter, the TOC and subcode of the CD and the lead-in area of the DVD will be described.
[0026]
2. CD TOC and subcode
Next, the TOC and subcode recorded in the lead-in area when the disc 90 is a CD will be described.
The minimum unit of data recorded on the disc 90 is one frame. One block (one subcoding frame) is composed of 98 frames.
[0027]
The structure of one frame is as shown in FIG.
One frame is composed of 588 bits, the head 24 bits are set as the synchronization data, and the subsequent margin bits by 3 bits are set, followed by 14 bits as the subcode data area. After that, 12 symbols of main data and 4 symbols of parity data are arranged.
[0028]
98 frames constitute one block, and the subcode data extracted from the 98 frames are collected to form one block of subcode data as shown in FIG.
The subcode data from the first and second frames (frame 98n + 1, frame 98n + 2) at the head of the 98 frames is a synchronization pattern. In the third frame to the 98th frame (frame 98n + 3 to frame 98n + 98), 96-bit channel data, that is, subcode data of P, Q, R, S, T, U, V, and W is formed. .
[0029]
Among these, the P channel and the Q channel used as reproduction management information are used for various controls related to reproduction such as access. However, the P channel only indicates a pause portion between tracks, and finer control is performed by the Q channel (Q1 to Q96). The 96-bit Q channel data is configured as shown in FIG.
The R channel to W channel data is provided to form a text data group, which will be described later.
[0030]
First, the 4 bits Q1 to Q4 are used as control data, and are used for the number of audio channels, emphasis, CD-ROM identification, and the like.
That is, 4-bit control data is defined as follows.
"0 ***" ... 2 channel audio
"1 ***" ... 4 channel audio
"* 0 **" ... CD-DA
"* 1 **" ... CD-ROM
"** 0 *" ... Digital copy not possible
"** 1 *" ··· Digital copy available
"*** 0" ... No pre-emphasis
"*** 1" ... Pre-emphasis available
[0031]
Next, 4 bits Q5 to Q8 are used as addresses, which are used as control bits for sub-Q data.
When the 4 bits of the address are “0001”, it indicates that the subsequent sub Q data of Q 9 to Q 80 is audio Q data, and when it is “0100”, the sub Q data of the subsequent Q 9 to Q 80 is video. Q data is indicated.
Q9 to Q80 are 72-bit sub-Q data, and the remaining Q81 to Q96 are CRC.
[0032]
In the lead-in area, the sub-Q data recorded there is TOC information.
That is, the 72-bit sub-Q data of Q9 to Q80 in the Q channel data read from the lead-in area has information as shown in FIG. The sub-Q data has 8-bit data.
[0033]
First, the track number is recorded. In the lead-in area, the track number is fixed to “00”.
Subsequently, POINT (point) is described, and further, MIN (minute), SEC (second), and FRAME (frame number) are indicated as the elapsed time in the track.
Further, PMIN, PSEC, and PFRAME are recorded. The meanings of PMIN, PSEC, and PFRAME are determined by the value of POINT as described below.
[0034]
When the value of POINT is “01h” to “99h” (h indicates that it is a hexadecimal expression), the value means a track number. In this case, in PMIN, PSEC, and PFRAME, the track number The start point (absolute time address) of the track is recorded as minute (PMIN), second (PSEC), and frame number (PFRAME).
[0035]
When the value of POINT is “A0h”, the track number of the first track is recorded in PMIN. Further, CD-DA, CD-I, and CD-ROM (XA specification) are distinguished by the value of PSEC.
When the value of POINT is “A1h”, the track number of the last track is recorded in PMIN.
When the value of POINT is “A2h”, the start point of the lead-out area is indicated as an absolute time address in PMIN, PSEC, and PFRAME.
[0036]
For example, in the case of a disc on which 6 tracks are recorded, data is recorded as TOC by such sub-Q data as shown in FIG.
As shown in FIG. 5, the track numbers TNO are all “00h”.
Block NO. Indicates the number of one unit of sub-Q data read as block data of 98 frames as described above.
Each TOC data has the same contents written over three blocks.
As shown in the figure, when POINT is "01h" to "06h", the start points of track # 1 to track # 6 are shown as PMIN, PSEC, and PFRAME.
[0037]
When POINT is “A0h”, “01” is indicated as the first track number in PMIN. Further, when the disc is identified by the value of PSEC and this disc is a CD-DA, PSEC = “00h” is set as shown. In the case of CD-ROM (XA specification), PSEC = “20h”, and in the case of CD-I, “10h”.
[0038]
The track number of the last track is recorded in PMIN at the position of “A1h” as the POINT value, and the start point of the lead-out area is set at the position of “A2h” as the POINT value in PMIN, PSEC, and PFRAME, respectively. Indicated.
After block n + 27, the contents of blocks n to n + 26 are repeatedly recorded.
[0039]
In tracks # 1 to #n on which data such as music is actually recorded on the disc 90 and the lead-out area, the sub-Q data recorded therein has the information shown in FIG. Have.
First, the track number is recorded. That is, each of the tracks # 1 to #n has a value of “01h” to “99h”. In the lead-out area, the track number is “AAh”.
Subsequently, information that can further subdivide each track is recorded as an index.
[0040]
Then, MIN (minute), SEC (second), and FRAME (frame number) are indicated as the elapsed time in the track.
Further, absolute time addresses are recorded as minutes (AMIN), seconds (ASEC), and frame numbers (AFRAME) as AMIN, ASEC, and AFRAME.
[0041]
Although the TOC and the subcode are formed in this way, it is understood that addresses on the disc, that is, AMIN, ASEC, and AFRAME are recorded in units of 98 frames.
These 98 frames (one block) are called one sub-coding frame, and 75 sub-coding frames are included in one second as audio data. That is, the possible values of “AFRAME” as an address are “0” to “74”.
In the case of a CD, the data capacity recorded on the disk 90 can be obtained from the absolute time address of each track recorded on the disk 90.
[0042]
3. Composition of DVD lead-in area
Next, a configuration example of the lead-in area when the disk 90 is a DVD will be described.
FIG. 6 is a schematic diagram showing a configuration example of the lead-in area.
As shown in the drawing, in the lead-in area, in addition to all “00h” data, a reference code (Reference_code) is recorded from the position of the absolute address “02000h” for 2 ECC blocks (hereinafter also simply referred to as a block). Control data (Control_data) is recorded in 192 blocks from the position of the absolute address “2F200h”. A block (ECC block) is a unit constituting an error correction block, and is formed by adding an error correction code to each 32-byte data, for example.
Also, the reference code and control data are recorded when cutting the master disc, and become read-only pit data. In addition, physical control information of the disk 90 is recorded as the control data.
[0043]
The standard code is provided so that various adjustments such as a focus position or an equalizer characteristic in the disk drive device 70 can be easily performed, and specific data including many shortest marks in a reproduced modulation pattern. Has been.
The control data records data indicating the physical specifications of the disk, such as the disk type, disk size, recording density, number of information planes (1 layer or 2 layers), sector number indicating a data area, and the like.
[0044]
FIG. 7 shows a configuration example of the control data block.
Each block of control data, which is 192 blocks, includes 16 sectors (1 sector = 2048 bytes).
Physical format information (Physical_format_information) is recorded in the sector of sector number 0. Further, in the sector of sector number 1, manufacturing information (Disc_Manufacturing_information) of the disc 90 is recorded. This is text data or code data that the disc manufacturer may record in free format.
Content provider information (Contents_Provider_infomation) is recorded in sectors of sector numbers 2 to 15.
[0045]
FIG. 8 shows the contents of the physical format information recorded in the sector number 0 together with the byte position (BP) and the number of bytes in the sector.
In byte position 0, a book type and a part version (Book_type_and_Part_version) are recorded. As the book type, a disc type such as a read-only disc or a rewritable disc is recorded by 4-bit data.
As part version, 4-bit version information is recorded.
In byte position 1, the disk size and the minimum lead-out rate (Disc_size_and_minimum_read-out_rate) are recorded by 4 bits each. The disk size is an 8 cm disk, a 12 cm disk, or other type information.
In byte position 2, a disc structure (Disc_structure) is recorded. Here, as shown in FIG. 9, “Single” (1 layer) or “Dual” (2 layers) is identified as the number of layers (Number_of_Layer), parallel tracks or opposite tracks are identified as track paths (Track_path), Information indicating whether or not an embossed user data area, a recordable user data area, a rewritable user data area, and the like is recorded as a layer type (Layer_Type).
[0046]
In byte position 3 shown in FIG. 8, linear density (linear density) and track density (track pitch) are recorded as information of recording density (Record_density) by 4 bits each.
Information of data area allocation (Data_area_allocation) is recorded in byte positions 4 to 15.
The contents of this data area allocation are shown in FIG. 10 together with the byte position (BP) and the number of bytes in the sector.
In FIG. 10, byte positions 4, 8, and 12 are set to “00h”. In byte positions 5 to 7, the start sector number (Start_sector_number_of_Data_Area) of the data area is recorded. Further, in byte positions 9 to 11, the end sector number (End_sector_number_of_Data_Area) of the data area is recorded. This indicates the last sector number formed in the data area, that is, the number of sectors formed in the data area.
[0047]
The byte positions 13 to 15 are set to “000000h” when the disc is a single layer (Single_layer) or a parallel track path, but when the disc is an opposit track path, A layer 0 end sector number (End_sector_number_in_Layer0) forming a track is recorded. Therefore, the data capacity of layer 0 can be grasped by this end sector number.
[0048]
In FIG. 8, information such as a BCA descriptor (BCA_discriptor) is recorded in byte position 16, and byte positions 17 to 31 and byte positions 32 to 2047 are reserved.
[0049]
4). Disk configuration
FIG. 11 is a schematic diagram showing a configuration of a single-layer disc (single layer), and shows a radial direction of the disc 90 in a cross-sectional view. As shown in the drawing, the lead-in area Rin0 shown in FIG. 6 is formed on the inner peripheral side of the disk 90, and a data area is further formed. Following this data area, a lead-out area Rout0 is formed. The data recording direction is the direction from the inner circumference side to the outer circumference side (arrow W).
Therefore, the disk rotation speed is set with the position corresponding to the end sector number (End_sector_number_of_Data_Area) of the data area allocation, that is, the outermost peripheral position of the data area being the outermost peripheral position of the disk 90.
[0050]
The track path (parallel track path, opposite track path) having a two-layer structure is as shown in the schematic diagrams of FIGS.
FIG. 12A shows the configuration of the parallel track path. As shown in the figure, a signal layer (layer 0, layer 1) having a two-layer structure is formed. Of these layers, layer 0 has the same configuration as the single-layer disc shown in FIG. That is, a lead-in area Rin1 is formed from the inner peripheral side of the disk 90, and a data area and a lead-out area Rout1 are formed toward the outer peripheral side.
The layer 1 has the same configuration as the layer 0. A lead-in area Rin2, a data area, and a lead-out area Rout2 are formed, and the recording direction is also the same. Accordingly, when the layer 0 end sector (End_LBA) is “n”, the sector “n + 1” following the sector “n” is recorded in the area following the layer 1 lead-in area Rin2.
[0051]
The parallel track path configured as described above is a track path suitable for highly interactive applications in which layer 0 and layer 1 information are associated with each other.
[0052]
In the opposite track path shown in FIG. 12B, a lead-in area Rin3 is formed on the inner side from layer 0, and a middle area Rmid1 is formed following the end sector (End_LBA) of the data area. The In layer 1, a middle area Rmid2 is formed on the outer peripheral side corresponding to the middle area Rmid1, a data area is formed on the inner peripheral side, and a lead-out area Rout3 is formed following the data area.
In such an opposite track path, the recording directions (arrow W) of layer 0 and layer 1 are reversed. That is, the data recorded in the layer 0 data area continues to the outer peripheral side of the layer 1 data area via the middle area Rmid1 and the layer 1 middle area Rmid2. That is, if the layer 0 end sector (End_LBA) is “n”, the sector “n + 1” following the sector “n” is the head data of the data area of layer 1 following the middle area Rmid2.
The disc 90 as the opposite track path is suitable for a highly continuous application such as a long movie.
[0053]
As described above, the identification of the single layer shown in FIG. 11 and the dual layer shown in FIG. 12 is shown in the lead-in area of the disk 90 as described above.
[0054]
In the present invention, the logical block address (end sector number) of data recorded on the outermost periphery of the data area is detected as the data capacity recorded on the disk 90, and the outermost periphery of the data area corresponding to this data capacity is detected. The disk 90 is rotated at a speed at which the maximum transfer rate in the disk drive device 70 can be obtained at the position.
For example, in the case of the single layer shown in FIG. 11, since data is recorded simply from the inner circumference side to the outer circumference side, the data capacity (end sector number) corresponds to the outermost circumference of the data area. .
[0055]
However, in the case of the dual-layer disc shown in FIG. 12, the data capacity and the outermost periphery of the data area do not necessarily match.
In the case of the parallel track path shown in FIG. 12A, the data following layer 0 continues to the inner circumference side of the data area in layer 1, so that the end sector (End_LBA) of layer 1 is A case may be considered where the layer 0 is located on the inner peripheral side from the end sector (End_LBA) of layer 0.
Therefore, in this example, in the case of the parallel track path, the end sector numbers (End_sector_number_of_Data_Area) recorded in the lead-in areas Rin1 and Rin2 of the layer 0 and layer 1 are compared, and the one with the larger number of sectors, that is, the capacity The end sector number of the higher layer is used as the data capacity of the disk 90.
[0056]
In the case of the opposite track path shown in FIG. 12B, the layer 1 end sector number (End_LBA) is positioned closer to the inner circumference as the data capacity increases. Accordingly, when the opposite track path is applied to the disk 90, the layer 0 end sector number (End_sector_number_in_Layer0) is set as the data capacity of the disk 90.
[0057]
Therefore, the logical block address of the data recorded on the outermost periphery of the data area is used as the data capacity of the disk 90 in either the single layer disk or the double layer disk (parallel track path, opposite track path). Then, assuming that the outermost periphery of the data area is the outermost periphery of the disk 90, the rotation of the disk that can obtain the maximum transfer rate in the disk drive device 70 is set and the rotation drive control is performed.
[0058]
By the way, the maximum number of sectors of a 12 cm disk that is a single layer is, for example, 2294920 (230488h). In this example, since the outermost periphery of one of the layers is also identified in the dual layer, the maximum number of sectors is the same.
Therefore, the maximum number of sectors detected in this example is a value of 2294920 or less.
[0059]
FIG. 13 is a diagram showing an example of the title, the number of sectors, and the time of a 12-cm disc having a single layer structure in which a movie or the like is recorded.
The title “A” indicates that a relatively long movie having a number of sectors of 2281183 and a time of 133 minutes is recorded. Next, the title “B” has 1904380 sectors and 107 minutes in time, the title “C” has 1695823 sectors and 40 minutes, and the title “D” has 961751 sectors and 30 minutes in time. ing. Therefore, in the case of a single-layer disc, the end sector number shown in FIG.
[0060]
FIG. 14 shows a 12-cm disk having a two-layer structure, for example.
In the title “E”, sectors from sector number 0 to 1759247 of layer 0 are recorded, and sectors from sector numbers 1759248 to 3527935 are recorded in layer 1. Therefore, although the maximum number of sectors as the disk is 3527935, if it is an opposite track path, the number of sectors “1759247” in layer 0 is set as the capacity of the disk in this example.
[0061]
The title “F” has sectors 0 to 1370499 recorded on layer 0, and layer 1 has sectors 1370500 to 2702172 recorded on it. However, in this example, the number of sectors “1370499” in layer 0 is used as the capacity of the disk.
Therefore, on a 12 cm disc, it can be assumed that, for example, 2 million or more sectors are formed in a relatively long movie. Although not shown, for example, the maximum number of sectors of an 8 cm disk is 633683.
[0062]
Therefore, in this example, the determination standard capacity when the disk 90 is a DVD is set in two stages, for example, 2000000 sectors and 633683 sectors, and the disk rotation speed is controlled in, for example, three stages as shown in FIG. I try to do it.
By setting the determination reference capacity in two stages, the disk rotation speed corresponding to each determination reference capacity can be set in three stages of speed 1 to speed 3, and based on the detected capacity of the disk 90, One of the speeds 1 to 3 is selected. However, speed 1 <speed 2 <speed 3 is satisfied, and the smaller the data capacity of the disk 90 is, the faster the speed is rotated, and the maximum transfer rate in the disk drive device 70 is realized without being affected by the data capacity of the disk 90. I have to.
[0063]
The relationship between the criterion capacity and the rotation speed is as shown in FIG. This figure is a schematic diagram showing the disk 90 from the front, and the position corresponding to the criterion capacity on the disk 90 is indicated by a broken line.
For example, when the disk capacity (end sector number) is 2000000 sectors or more (e.g., corresponding to point A), the disk capacity is rotated at a speed of 1 and the disk capacity is also set to 2000000 sectors or less and 633683 sectors or more (e.g., B Rotate at speed 2). Then, when it is set to 636383 sectors or less (for example, corresponding to the point C), it is rotated at a speed of 3.
As a result, the maximum transfer rate in the disk drive device 70 obtained at point A can be obtained at point B or C.
[0064]
5. Rotation speed setting
FIG. 17 is a flowchart for explaining an example of process transition from detection of the capacity of the loaded disk 90 to rotation control.
First, the disk drive device 70 determines whether or not it is in an initial state (Unit Attention Control) (S001). The initial state is, for example, a state such as “Power on Reset”, “Hard Reset”, or “New Media Insertion”, and when these states are detected, the process proceeds to the subsequent processing steps.
When the initial state is detected, disc discrimination is performed (S002). Here, for example, the type of the disk 90 such as a DVD or a CD is determined based on various information recorded in the lead-in area, and the required spin-up control is performed based on the determination result ( S003). In this case, pick-up operation control is performed according to the disc type determined in step S002.
[0065]
Thereafter, control is performed to rotate the disk 90 at a required rotational speed based on the determination result in step S002.
First, it is determined whether or not the disk 90 is a DVD (S004). If it is determined that the disk 90 is a DVD, the process further proceeds to a DVD determination process (S005).
[0066]
Here, the DVD discrimination processing as step S005 will be described with reference to FIG.
As the DVD discrimination processing, first, the content of “Number_of_Layer” in the disc structure (Disc_Structure) of the physical format information is discriminated (S101). If the determination result here is a single-layer disc, the end sector number is used as the data capacity (S102).
[0067]
If the disc is a dual layer (DUAL) disc, the track path is further discriminated (S103). If it is determined that the track path is a parallel track path, the end sector numbers recorded in the lead-in areas Rin1 and Rin2 of the layer 0 and layer 1 are compared. The data capacity is set (S104). If the track path determination result is an opposite track path, the layer 0 end sector number (End_sector_number_in_Layer0) is set as the data capacity (S105).
Thus, in step S005, the capacity of the data recorded on the disk 90 is detected.
[0068]
After the DVD discrimination processing in step S005, the process proceeds to step S006 shown in FIG. 17, and the data capacity detected in step S005 is compared with the judgment reference capacity 1 (200000 sectors) (S006). If the data capacity is larger than the criterion capacity 1, the disk rotation speed 1 is set (S007). If the data capacity is smaller than the determination standard capacity 1, the data capacity is compared with the determination standard capacity 2 (sector number 633683) (S008). If the data capacity is larger than the determination reference capacity 2, the disk rotation speed 2 is set (S009). If the data capacity is smaller than the determination standard capacity 2, the disk rotation speed 3 is set (S010).
Thereafter, control is performed to rotate the disk 90 at the disk rotation speed set in this way (S011).
[0069]
If it is determined in step S004 that it is not a DVD, it is determined whether or not it is a CD (S012). If it is determined that the disc is not a CD, it is recognized that the disc 90 loaded in the disc drive device 70 is not, for example, a CD or DVD, or that the disc 90 is defective, for example. Escape from processing.
If it is determined that it is a CD, it is determined whether or not the data capacity (absolute time address) of the CD is larger than the determination reference capacity 3 (S013). As a CD, a maximum performance time of, for example, 74 minutes is possible with a 12 cm disc, and a maximum performance time of, for example, 20 minutes is possible with an 8 cm disc (single CD). Accordingly, the determination standard capacity 3 may be a data capacity corresponding to, for example, about 40 minutes, and the determination standard capacity 4 shown below may be a data capacity corresponding to, for example, about 20 minutes.
[0070]
If it is determined in step S013 that the data capacity is larger than the determination reference capacity 3, the disk rotation speed 4 is set (S014). If it is determined that the data capacity is smaller than the determination standard capacity 3, it is determined whether or not the data capacity is larger than the determination standard capacity 4 (S015). If the data capacity is larger than the criterion capacity 4, the disk rotation speed 5 is set (S016). If the data capacity is smaller than the criterion capacity 4, the disk rotation speed 6 is set (S017).
In step S014, step S016, and step S017, control is performed to rotate the disk 90 at the set disk rotation speed (S011).
The disk rotation speeds 4, 5, and 6 correspond to the disk rotation speeds 1 to 3, and the speed 4 <speed 5 <speed 6 is satisfied. The smaller the data capacity of the disk 90, the higher the rotation speed. The maximum transfer rate in the disk drive 70 is realized without being affected by the data capacity of 90.
[0071]
In this way, by setting the rotational speed of the disk 90 according to the data capacity of the disk 90, the maximum transfer that can be realized in the signal processing of the disk drive device 70 even for the disk 90 with a small data capacity. You will be able to get the rate.
[0072]
In the above embodiment, the disk rotation speed is set in accordance with the data capacity of the disk 90. However, in the case of a DVD, for example, the diameter (12 cm or 8 cm) of the disk 90 is detected and the detected diameter is set. A corresponding rotation speed may be set.
FIG. 19 is a flowchart for explaining an example of setting the rotation speed in accordance with the disc diameter of the DVD. Note that the flowchart shown in this figure corresponds to the processing steps from step S005 to step S010 shown in FIG.
That is, when it is determined that the disk 90 loaded in the disk drive device 70 is a DVD, the content of “Disc size” in the logical format information is determined (S301). If it is determined that the disc is a 12 cm disc, the disc rotational speed is set to “L” (S302). This rotational speed “L” is, for example, a standard speed for rotating a 12 cm disc. It is said. If the determination result in step S301 is an 8 cm disc, the disc rotation speed is set to, for example, “L” × 2 (S303).
That is, for an 8 cm disk, a higher transfer rate can be obtained by setting a rotational speed that is, for example, about twice that of a 12 cm disk.
[0073]
In FIG. 18, the 8 cm disk is rotated at a speed that is, for example, twice that of 12 cm. However, as described with reference to FIG. It is also possible to set a rotation speed at which the maximum data transfer rate in the disk drive device 70 can be obtained.
[0074]
In this example, for example, a disk on which data is recorded corresponding to the CLV method is rotated by the CAV method. However, in the present invention, data recording is performed by the Partial-CAV method, for example. The present invention can also be applied when the disk is rotated by the CAV method.
[0075]
【The invention's effect】
As described above, according to the present invention, the rotational speed of the disk is set based on the data capacity of the disk, and data is read while the set rotational speed is maintained. Therefore, there is no need to change the rotation speed according to the position of the pickup as in the CLV method, for example, and data can be read while reducing various processing loads.
Further, as the disk rotation speed based on the data capacity, the maximum data transfer rate in the reproducing apparatus can be obtained at the outermost periphery of the recording area. This makes it possible to maximize the transfer capability even for a disk with a small data capacity.
[0076]
When reading data from a dual-layer disc to which a parallel track path is applied, the end sector number (logical block address) of the lead-in area corresponding to each recording surface formed on each layer is compared. The end sector number closer to the outer periphery of the disk is detected as the data capacity. Therefore, the outermost periphery of the recording area can be detected even when the data volume recorded on the recording surface of each layer is different.
[0077]
Further, the rotational speed of the disk is set based on the diameter of the disk, and data is read out while maintaining the set rotational speed. Also in this case, since the rotational speed of the disk can be made constant, data reading can be performed while reducing various processing burdens.
Further, the maximum data transfer rate can be obtained even for a small disk having a diameter of, for example, 8 cm.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration example of a disk drive device according to an embodiment of this invention.
FIG. 2 is an explanatory diagram of a frame structure of a disc (CD).
FIG. 3 is an explanatory diagram of sub-coding of a disc (CD).
FIG. 4 is an explanatory diagram of sub-Q data of a disc (CD).
FIG. 5 is an explanatory diagram of TOC data of a disc (CD).
FIG. 6 is an explanatory diagram of a lead-in area of a disc (DVD).
7 is an explanatory diagram of control data in the lead-in area shown in FIG. 6. FIG.
FIG. 8 is an explanatory diagram of physical format information of the control data shown in FIG.
FIG. 9 is an explanatory diagram of disk structure information in physical format information.
FIG. 10 is an explanatory diagram of data area allocation information in physical format information.
FIG. 11 is a schematic diagram illustrating the configuration of a single-layer disc.
FIG. 12 is a schematic diagram illustrating the configuration of a dual-layer disc.
FIG. 13 is a diagram for explaining an example of the number of sectors in a single-layer disc.
FIG. 14 is a diagram for explaining an example of the number of sectors in a dual-layer disc.
FIG. 15 is a diagram for explaining a relationship between a determination reference capacity and a disk rotation speed.
FIG. 16 is a diagram for explaining a relationship between a determination reference capacity and a disk rotation speed.
FIG. 17 is a diagram for explaining a process for setting the disc rotation speed based on the determination reference capacity.
FIG. 18 is a diagram for explaining a discriminating process for a dual layer disc in a DVD.
FIG. 19 is a diagram for explaining a process for setting the disc rotation speed based on the disc diameter.
[Explanation of symbols]
1 pickup, 9 RF amplifier, 10 system controller, 12 decoder, 14 servo processor, 21 FG, 22 memory, 70 playback device, 90 disc

Claims (3)

In a playback device capable of playing a disc,
Disk rotating means for rotating the loaded disk;
A discriminating means for discriminating the type of the disc;
A detection means for the data to the logical block address of the data recorded in the most outer circumference of the data area is recorded, detects from the management information area before the SL disk,
Detection result detected by the detection means, performs control of the disk rotation means based on the discrimination result of said discriminating means, and control means for performing control to rotate the disk at a predetermined rotational speed,
After discriminating the type of the disc by the discriminating means, the data capacity of the disc is detected based on the discriminating result, the data recording method of the disc and the detection result detected by the detecting means, The reproducing apparatus characterized in that the rotational speed of the disk is set by comparing the detected data capacity with a predetermined determination capacity.   The control means controls the disk rotation means based on the data capacity detected by the capacity detection means so that the data recorded on the outermost periphery can be read at the maximum transfer rate in the reproducing apparatus. The playback apparatus according to claim 1, wherein the playback apparatus is configured as described above. A disc structure identifying means capable of identifying the structure of the recording surface of the disc from the disc management information area;
By the disc structure identification means, the disc has a recording layer having a two-layer structure, and the recording on the first recording surface formed on the first layer and the second recording surface formed on the second layer is performed. When it is identified that the direction is the same as the radial direction of the disk, the capacity detecting means compares the logical block addresses of the data recorded on the outermost circumference on the first and second recording surfaces. 2. The reproducing apparatus according to claim 1, wherein a logical block address closer to the outer periphery of the disk is used as the data capacity.

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