JP4441840B2 - Disc-shaped recording medium, recording apparatus, and recording method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention is a disc-shaped recording medium. ,Record Recorder and Record Regarding the method, for example, a write once (WO) optical disc such as a CD-R (Compact Disc Recordable) in which information can be written only once at the same location, or a rewritable such as CD-RW in which information can be rewritten to the same location as many times as possible. The present invention is suitable for application to an optical disc apparatus that reads and writes data on an (RW: Rewritable) type optical disc.
[0002]
[Prior art]
Conventionally, in this type of optical disc apparatus, data (hereinafter referred to as original data) given from a host computer is sequentially stored in a buffer memory, and then CIRC (Cross Interleave Reed-Solomon Code) encoding processing and EFM (EFM) A predetermined recording data process such as an Eight to Fourteen Modulation (modulation) process is performed, and the obtained data in a predetermined format is written on an optical disc (CR-R, CD-RW) via an optical pickup.
[0003]
[Problems to be solved by the invention]
By the way, in a conventional optical disk (hereinafter referred to as a normal type optical disk) used in such an optical disk device, writing is performed 1 to 4 times as high as the reading speed at a normal linear linear velocity (CLV). It is set so that writing can be performed at a speed (hereinafter referred to as a low speed writing speed) or a writing speed of 8 to 10 times (hereinafter referred to as a high speed writing speed).
[0004]
In recent years, in addition to this, an optical disc capable of writing at a higher speed than a normal type optical disc (hereinafter referred to as a special type optical disc) has been proposed, and the special type optical disc is read at a normal constant linear velocity (CLV). The writing speed is set to be 8 to 16 times or 8 to 20 times the speed (hereinafter referred to as an ultra-high speed writing speed).
[0005]
However, when a special type optical disc is loaded in an optical disc apparatus in which only a normal type optical disc can be written, if new information is added to the recording format of the lead-in area on the recording surface, the lead-in area When reading, there is a risk of causing confusion or malfunction, and there is a risk that the write inhibit operation may be activated depending on the model.
[0006]
Therefore, a method of adding information for discriminating whether the optical disc is a special type optical disc or a normal type optical disc to the recording format of the recording surface lead-out is conceivable, but it is located on the outer peripheral side from the lead-in area located on the inner peripheral side of the recording surface. While it takes a long time to reach the lead-out area, there is a problem in that it is difficult for the user to perform the reading operation even in the case of a normal type optical disk that does not need to be read.
[0007]
The present invention has been made in consideration of the above points, and a disc-shaped recording medium capable of significantly improving the use efficiency for the user. , Recording device and Record We are going to propose a method.
[0008]
[Means for Solving the Problems]
In order to solve such a problem, in the present invention, in a disc-shaped recording medium in which the first information is written in the first recording area and the second information can be written according to the description content of the first information. The third information can be obtained from the configuration of the plurality of elements without adding a new type of element different from the plurality of elements forming one information. In the description content of the third information, among the plurality of elements forming the first information, the order or continuity of each element that is cyclically repeatedly expressed is changed. .
[0009]
As a result, in this disc-shaped recording medium, the third information is composed only of existing information without adding any new types of elements to the description content of the first information, so that efficiency is limited within a limited area. Information can be used.
[0014]
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
[0015]
(1) Configuration of optical disc according to the present embodiment
In FIG. 1, reference numeral 1 denotes an optical disc apparatus according to the present embodiment as a whole. Data D1 given from a host computer 2 is recorded on an optical disc (CD-R, CD-RW) 3 or reproduced from the optical disc 3. It has been made so that it can.
[0016]
That is, in the optical disc apparatus 1, in the recording mode, data sequentially given from the host computer 2 is taken in through the interface unit 4 and is sequentially stored in the buffer memory 6 through the encoder unit 5. Yes.
[0017]
The encoder unit 5 includes a layered ECC (Error Correcting Code) addition processing unit 7, a CIRC (Cross interleave Reed-Solomon Coad) encoding processing unit 8, and an EFM (Eight to Fourteen Modulation) modulation processing unit 9. The stored data D1 is sequentially read out in units of sectors (2 [kbyte] units), and an error correction code is added to the data D1 by the layered ECC adding unit 7, and CIRC encoding processing unit 8 inserts CIRC encoding processing and synchronous data Then, after the EFM modulation processing unit 9 performs the EFM modulation processing, the write data D2 thus obtained is sent to the optical pickup 11 via the RF amplifier 10.
[0018]
The optical pickup 11 has an optical system device such as a laser diode, a collimator lens, an objective lens and a light receiving element, and an electrical system device such as a laser diode driver, and a light beam L1 modulated in accordance with supplied write data D2. Is irradiated onto the recording surface of the optical disc 3.
[0019]
At this time, the optical pickup 11 generates a servo error signal S1 such as a tracking error signal and a focus error signal and a push-pull signal S2 based on the reflected light L2 from the optical disc 3, and the servo error signal S1 is generated by the RF amplifier 10. And a push-pull signal S2 is sent to an ATIP (Absolute Time In Pre-groove) decoder unit 13.
[0020]
The servo control unit 12 drives the optical disc 3 to rotate at a predetermined speed by controlling the spindle motor 15 via the spindle driver 14 based on the supplied servo error signal S1. The servo controller 12 controls the sled motor 17 via the sled driver 16 based on the servo error signal S1, thereby causing the beam spot of the light beam L1 on the optical disc 3 (hereinafter simply referred to as a beam spot). Is moved in the radial direction of the disk 3 along a data track (pre-groove or land) formed on the recording surface of the optical disk 3. Further, the servo control unit 12 performs tracking control and focus control by controlling a biaxial actuator (not shown) in the optical pickup 11 via the biaxial actuator driver 18 based on the servo error signal S1.
[0021]
On the other hand, the ATIP decoder unit 13 detects the absolute address of the beam spot at that time in the optical disc 3 by decoding the supplied push-pull signal S2, and sends this to a CPU (Central Processing Unit) 19.
[0022]
That is, the ATIP decoder unit 13 is included in the push-pull signal S2 by passing the push-pull signal S1 through a band-pass filter circuit in the range of ± 1 [kHz] having a center frequency of 22.05 [Hz] provided therein. The wobble component is extracted and FM demodulation processing is performed on the wobble component to detect the absolute address on the optical disc 3 where the beam spot is located at that time, and this is sent to the CPU 19 as absolute time information S3.
[0023]
Also, the ATIP decoder 13 section is a sync interrupt that notifies this whenever the absolute address on the optical disk 3 obtained by the decoding process as described above changes (that is, whenever the sector that the beam spot scans on the optical disk changes). The signal S4 is sent to the CPU 19.
[0024]
Thus, the CPU 19 sequentially recognizes the current recording position on the optical disk 3 based on the absolute time information signal S3 and the sync interrupt signal S4 given from the ATIP decoder unit 13, and records the data D2 based on the recognition result. Necessary control processing is executed so that the data can be correctly recorded on the optical disc 3.
[0025]
On the other hand, in the reproduction mode, the CPU 19 controls the servo control unit 12 to rotate the optical disc 3 at a predetermined speed and control the beam spot to the data track of the optical disc 3 in the same manner as in the recording mode. And tracking control and focus control are performed.
[0026]
Further, the CPU 19 drives the laser diode in the optical pickup 11 described above to emit the light beam L1 toward the optical disc 3. As a result, the light beam L1 is reflected on the recording surface of the optical disc 3, and read data D3 read from the optical disc 3 as an RF signal obtained based on the reflected light is read from the optical pickup 11 via the RF amplifier 10 to the decoder section. 20 is given.
[0027]
The decoder unit 20 includes a PLL (Phase Locked Loop) circuit 21, a synchronization data detection unit 22, an EFM demodulation unit 23, a CIRC decoding unit 24, and a layered ECC demodulation unit 25, and read data supplied in the PLL circuit 21. The clock is extracted from D3, and the extracted clock CLK is sent to the synchronous data detector 22 together with the read data D3.
[0028]
The synchronization data detection unit 22 generates a synchronization data detection window pulse having a pulse width larger by a predetermined pit before and after the above-described synchronization data data pattern based on the supplied clock CLK. Then, the synchronization data detection unit 22 sequentially detects the synchronization data detection window pulses, and sequentially sends the read data D3 to the EFM demodulation unit 23 in predetermined units based on the detection result.
[0029]
The read data D3 is then EFM demodulated in the EFM demodulator 23, CIRC decoded in the CIRC decoder 24, and further subjected to error correction in the layered ECC demodulator 25, so that the original data before recording is recorded. After that, the data is converted to the data of the following format and sent to the host computer 2 through the interface circuit 4.
[0030]
In this manner, the optical disc apparatus 1 can record the data D1 given from the host computer 2 on the optical disc 3, or reproduce the data recorded on the optical disc 3 and send it to the host computer 2. Has been made.
[0031]
(2) Optical disc recording format
In practice, in this optical disc apparatus 1, additional information for improving the usability of the user is recorded on the recording surface of the optical disc 3 in addition to the program area A1 in which the digital audio data (that is, read data) D3 is recorded. The subcode data area A2 is allocated.
[0032]
The subcode data area A2 includes a power calibration area (PCA) A2A, a program memory area (PMA) A2B, a lead-in area A2C, and a lead-out area A2D.
[0033]
On the recording surface 3A of the optical disc 3, as shown in FIG. 2, a power calibration area (PCA) A2A, a program memory area (PMA) A2B, a lead-in area A2C, a program area A1, and a lead-out area A2D are arranged in this order. Recorded sequentially from the inner periphery.
[0034]
In this case, the arrangement and contents of each area on the recording surface 3A of the optical disc 3 are determined in accordance with a physical format defined by a so-called Orange Book.
[0035]
Among these, the power calibration area (PCA) A2A is an area used for light amount control of the laser diode in the optical pickup 11. The program memory area (PMA) A2B is an area for temporarily holding various information related to the recording process of the optical disc 3.
[0036]
Here, the power calibration is optimal for suppressing occurrence of a data track (pre-groove or land) formed on the recording surface 3A of the optical disc 3 deviating from a predetermined reference range (hereinafter referred to as asymmetry). As soon as the recording mode is started, the writing speed that can be set to the optical disc 3 and the material of the optical disc 3 are adjusted while performing trial writing in the power calibration area (PCA) A2A immediately after the start of the recording mode. In response, it means controlling the light quantity of the laser diode.
[0037]
Furthermore, the lead-in area A2C is an area serving as an introduction part for setting the recording start of the digital audio data D3 recorded in the program area A1. Further, the lead-out area A2D is an area serving as a derivation unit for setting the end of recording of the digital audio data D3 recorded in the program area A1.
[0038]
Of these, a subcode signal consisting of a block unit of the supplied digital audio data D3 is written in the lead-in area A2D. As shown in FIG. 3, the one block is a combination of 98 frames having a predetermined data structure, and the 8-channel subcodes P, Q, R, S, T, U, V, and W are included. It is logically configured as the smallest unit that makes sense.
[0039]
Specifically, as shown in FIG. 4, one frame includes 24-bit frame synchronization information and 8-channel subcodes P, Q, R, S, T, U, V, and 1 bit assigned to each channel. 14 bits of subcode information obtained by EFM modulation of 8-bit fixed-length data consisting of W and 32 pieces (32 symbols) of 14-bit audio data obtained by EFM modulation of 8-bit audio data It is composed of audio information that is sequentially connected with 3 bits for connection.
[0040]
Among the subcode signals, data corresponding to the Q channel (hereinafter referred to as subcode Q data) DQ is “S0, S1” representing a part of the synchronization pattern, as shown in FIG. “CONTROL” indicating control signals such as the number of channels and presence / absence of pre-emphasis, “ADR” indicating various modes and address information, “TNO” indicating track number, “POINT” indicating index number, and elapsed time in the song “MIN”, “SEC” and “FRAME” expressed as absolute time information, “ZERO” reserved as a reserve for defining commands and the like in the future, “PMIN” indicating elapsed time in the music as relative time information , “PSEC” and “PFRAME”, “CRC (Cyclic Redundancy Check)” representing a cyclic redundancy check for detecting an error in data transmission It is sequentially written in the order.
[0041]
The description contents of the subcode Q data DQ are divided into a lead-in area A2C, a program area A1 and a lead-out area A2D, and different contents are described respectively.
[0042]
Among these, the arrangement pattern of the absolute time information corresponding to the lead-in area A2C in the subcode Q data DQ is standardized by the so-called Orange Book, and the time for 9 frames after the extra information for 1 frame. It is defined to repeat continuously and cyclically in units of 10 frames arranged so that code information continues.
[0043]
As such extra information, in the case of a CD-RW optical disc, special information SI1 to SI3 and additional information AI1 and AI2 are defined. Incidentally, although the additional information AI3 is actually defined, it is currently reserved as a reserve for future use.
[0044]
Of these, the special information SI1 depends on the type of the optical disc 3 (for example, CD-R or CD-RW, 8 [cm] or 16 [cm], normal type optical disc or special type optical disc, etc.) and each writing speed. The special information SI2 is the start time of the lead-in area A2C, the special information SI3 is the finally settable start time of the lead-out area A2D, and the additional information AI1 is the optical disc 3 In the additional information AI2, such as a write speed that can be set for the light beam, an appropriate light beam power or the like is described for suppressing the generation of asymmetry corresponding to each write speed.
[0045]
Actually, the absolute time information embedded in the pregroove is also described as a binary code assigned to “MIN”, “SEC”, and “FRAME” representing the absolute time information in the subcode Q data DQ.
[0046]
For example, when “MIN”, “SEC”, and “FRAME” are represented by M1, S1, and F1, respectively, (M1, S1, F1) = (0, 0, 0) is the time of the program area A1 and the lead-out area A2D. (M1, S1, F1) = (1, 0, 0) represents time code information of the power calibration area (PCA) A2A, program memory area (PMA) A2B, and lead-in area A2C. (M1, S1, F1) = (1, 0, 1) represents special information SI1, (M1, S1, F1) = (1, 1, 0) represents special information SI2, and (M1, S1) , F1) = (1, 1, 1) represents special information SI3. Further, (M1, S1, F1) = (0, 0, 1) represents additional information AI1, (M1, S1, F1) = (0, 1, 0) represents additional information AI2, and (M1, S1 , F1) = (0, 1, 1) represents additional information AI3.
[0047]
In this way, the absolute time information corresponding to the lead-in area A2C is the order in which the extra information for one frame is cyclically repeated with the special information SI1, SI2, SI3 and the additional information AI1, AI2, as shown in FIG. (Hereinafter, this is referred to as a normal type discrimination order), and it is defined that time code information for nine frames is arranged following the extra information.
[0048]
In the present embodiment, the description content of absolute time information corresponding to the lead-in area A2C on the recording surface 3A of the optical disc 3 is set in a predetermined state in advance, and the CPU 19 sequentially reads from the optical disc 3 in the recording mode. While the description contents of the absolute time information are sequentially stored in the memory 30 (FIG. 1), based on the data contents stored in the memory 30, the currently loaded optical disk 3 is a normal type optical disk or a special type optical disk. In the case of a special type optical disc, the description content of absolute time information corresponding to the lead-out area A2C is read.
[0049]
Incidentally, in the present embodiment, the absolute time information corresponding to the lead-out area A2D on the recording surface 3A of the optical disc 3 is also described with substantially the same content as the absolute time information corresponding to the lead-in area A2C described above. Write power and the like are set with parameters corresponding to the ultra-high speed writing speed peculiar to the special type optical disc.
[0050]
(3) Description of Absolute Time Information Corresponding to Lead-in Area According to the Present Embodiment In the conventional normal type optical disc, the absolute time information corresponding to lead-in area A2C is 9 frames worth as shown in FIG. The order of arrangement is defined so that extra information for one frame arranged in the preceding stage of each time code information is cyclically assigned in the normal type discrimination order such as special information SI1, SI2, SI3 and additional information AI1, AI2. ing.
[0051]
In the case of the present embodiment, the absolute time information corresponding to the lead-in area A2C on the special type optical disc is such that the arrangement order of the extra information for one frame arranged in the preceding stage of each time code information for nine frames is the normal time described above. A predetermined arrangement order different from the type discrimination order (hereinafter referred to as a special type discrimination order) is set.
[0052]
In this case, for example, as shown in FIG. 7, the special information SI3, SI2, SI1 and the additional information AI2, AI1 are used as the special type determination order of the extra information for one frame arranged in the preceding stage of the time code information for nine frames. It is set to be assigned in order.
[0053]
(4) Write setting processing procedure RT1
Next, a series of processing procedures of the CPU 19 in the recording mode of the optical disc apparatus 1 will be described. In this optical disk apparatus, when the optical disk is loaded by the user, the CPU 19 starts the write setting processing procedure RT1 shown in FIG. 8 from step SP0, and continues to step SP1 to determine the type of the loaded optical disk (for example, CD-R or CD -RW, 8 [cm] or 16 [cm]) based on the description content of the subcode Q data DQ of the lead-in area A2C recorded on the recording surface.
[0054]
Subsequently, the CPU 19 proceeds to step SP2, waits for a command from the host computer 2, and when it eventually obtains an affirmative result, proceeds to step SP3 to execute a command (that is, a write command) that the given command executes a write operation. It is determined whether or not.
[0055]
If a negative result is obtained in step SP3, this indicates that the given command is a command other than the write command. At this time, the CPU 19 proceeds to step SP4 and executes the command. Then, the process returns to step SP2 again to wait for a command from the host computer 2.
[0056]
On the other hand, when a positive result is obtained in step SP3, the CPU 19 proceeds to step SP5, and based on the arrangement order of the absolute time information corresponding to the lead-in area A2C of the recording surface 3A of the loaded optical disk 3. Then, it is determined whether or not the optical disc 3 is a special type optical disc.
[0057]
If an affirmative result is obtained in step SP5, this indicates that the loaded optical disk 3 is a special type optical disk. At this time, the CPU 19 proceeds to step SP6 to read the recording surface 3A of the optical disk 3. By reading the description content of the absolute time information corresponding to the out area A2D, the write power and the like are set with parameters according to the ultra-high speed writing speed, and then the process proceeds to step SP7.
[0058]
On the other hand, if a negative result is obtained in step SP5, this indicates that the loaded optical disk is a normal type optical disk. At this time, the CPU 19 proceeds directly to step SP7.
[0059]
In step SP7, the CPU 19 determines whether or not the power calibration described above has been completed for the optical disc 3, and proceeds to step SP8 as it is when an affirmative result is obtained, while it proceeds to step SP8 when a negative result is obtained. After proceeding to SP9 and executing power calibration, the process proceeds to step SP8.
[0060]
In step SP8, the CPU 19 writes the digital audio data D3 in the program area A1 on the recording surface 3A of the optical disc 3, and then proceeds to step SP9 and waits for the writing operation of the digital audio data D3 to end. It returns to step SP2 again and waits for a command from the host computer 2.
[0061]
In this manner, in this optical disc apparatus 1, based on the arrangement pattern of absolute time information corresponding to the lead-in area A2C of the recording surface 3A of the loaded optical disc 3, the optical disc 3 is a special type optical disc or a normal type optical disc. In addition, the description content of the absolute time information corresponding to the lead-out area A2D can be read only in the case of a special type optical disc.
[0062]
(5) Discrimination mode processing procedure RT2
Actually, in this optical disc apparatus 1, the CPU 19 executes the discrimination mode processing procedure RT2 shown in FIG. 9 from step SP10 in step SP5 of the write setting processing procedure RT1 (FIG. 8) described above, thereby loading the loaded optical disc 3. Is a normal type optical disc or a special type optical disc.
[0063]
In subsequent step SP11, the CPU 19 moves the optical pickup 11 to the start position of the lead-in area A2C on the recording surface 3A of the optical disc 3, and then proceeds to step SP12 to obtain absolute time information corresponding to the lead-in area A2C. Read sequentially.
[0064]
In step SP13, the CPU 19 determines whether or not the extra information (special information SI1, SI2, SI3 or additional information AI1, AI2) is included in the read absolute time information, and when a positive result is obtained. In step SP14, the extra information is stored in the memory.
[0065]
On the other hand, when a negative result is obtained in step SP13, this indicates that only time code information is included in the absolute time information. At this time, the CPU 19 returns to step SP13 again and an affirmative result is obtained. Wait for it to be obtained.
[0066]
Subsequently, the CPU 19 proceeds to step SP15 and determines whether or not the extra information is already stored in the memory 30 based on the rising or falling state of the flag set for each extra information.
[0067]
If an affirmative result is obtained in step SP15, this indicates that another extra information has already been stored in the memory 30 after reading the absolute time information. At this time, the CPU 19 proceeds to step SP16. It is determined whether or not the extra information already stored in the memory 30 and the extra information stored in the memory 30 correspond to a part of the normal type determination order described above.
[0068]
If an affirmative result is obtained in step SP16, this indicates that the currently loaded optical disk 3 is a normal type optical disk. At this time, the CPU 19 proceeds to step SP17 as it is, and the write setting processing procedure RT1 described above. Then, the process proceeds to step SP6 (FIG. 8), and then proceeds to step SP18 to end the determination mode processing procedure RT2.
[0069]
On the other hand, if a negative result is obtained in step SP16, the CPU 19 proceeds to step SP19, in which the extra information already stored in the memory 30 and the extra information stored in the memory 30 are determined as the special type described above. It is determined whether or not it is a part of the determination order.
[0070]
If an affirmative result is obtained in step SP19, this indicates that the currently loaded optical disk 3 is a special type optical disk. At this time, the CPU 19 proceeds to step SP27 as it is, and the write setting processing procedure RT1 described above. Then, the process proceeds to step SP7 (FIG. 8), and then proceeds to step SP18 to end the determination mode processing procedure RT2.
[0071]
On the other hand, if a negative result is obtained in step SP19, this indicates that the currently loaded optical disk 3 is neither a normal type optical disc nor a special type optical disc. At this time, the CPU 19 proceeds to step SP21 and performs a predetermined error. After notifying the host computer 2 of the message, the process proceeds to step SP18 to end the determination mode processing procedure RT2.
[0072]
As described above, in the optical disc apparatus 1, the CPU 19 stores the extra information of the absolute time information sequentially read from the optical disc 3 in the memory 30 and sequentially stores the optical disc 3 currently loaded based on the arrangement order of the extra information. Is a normal type optical disc or a special type optical disc.
[0073]
(6) Operations and effects according to this embodiment
In the above configuration, in the optical disc apparatus 1, when a write command is given from the host computer 2, the CPU 19 reads absolute time information corresponding to the lead-in area A2C of the recording surface 3A of the loaded optical disc 3. However, only the extra information of the read absolute time information is sequentially stored in the memory 30.
[0074]
Subsequently, the CPU 19 recognizes whether the special type discriminating order is the special type discriminating order or the normal type discriminating order based on the order of the continuous extra information stored in the memory 30, so that the optical disc 3 is the special type optical disc. Or a normal type optical disc.
[0075]
Therefore, without adding new information to the description content of the lead-in area A2C on the recording surface 3A of the optical disc 3, only based on a change in the arrangement order of the extra information already defined in the so-called Orange Book, It is possible to easily distinguish between a special type optical disk and a normal type optical disk.
[0076]
As a result, in the optical disk apparatus capable of writing only the normal type optical disk, the special type disk can be recognized on the basis of the normal writing operation without causing any confusion or trouble, and the special type optical disk can also be written. Also in the apparatus, it is possible to recognize a special type optical disk based on a normal writing operation and to set the write power and the like with parameters according to the ultra high speed.
[0077]
According to the above configuration, in the optical disc apparatus 1, when a write command is given from the host computer 2, for the loaded optical disc 3, the absolute time information corresponding to the lead-in area A2C of the recording surface 3A is continuous. The description content of the lead-in area A2C on the recording surface 3A of the optical disc 3 is determined by determining whether the optical disc 3 is a special type optical disc or a normal type optical disc based on the arrangement order of the extra information to be performed. As a result, the special type optical disc can be easily recognized even in an optical disc apparatus capable of writing only a normal type disc, and the use efficiency can be remarkably improved for the user.
[0078]
(7) Other embodiments
As described above, in the present embodiment, the case where the present invention is applied to the optical disc apparatus 1 compatible with CD-RW has been described. However, the present invention is not limited to this, and for example, CD-R, DVD Widely used in various recording devices other than various recording media such as (Digital Versatile Disc) -R or DVD-RW, writable optical discs, and magneto-optical discs such as MO (Magneto Optical Disk) discs. Can be applied.
[0079]
In this case, according to the description content of the absolute time information (first information) written in the lead-in area A2C (first recording area) in the normal type optical disc (first disc-shaped recording medium) as the recording device. Although the case where the optical disc apparatus 1 for writing the digital audio data (second information) D3 on the normal type optical disc is applied has been described, the present invention is not limited to this and corresponds to the recording format of the disc-shaped recording medium. You may make it apply to the recording apparatus which consists of various structures.
[0080]
Incidentally, in the CD-R optical disc, the extra information of the absolute time information corresponding to the lead-in area A2C described above is defined in a so-called orange book so as to include only the special information SI1, SI2, and SI3.
[0081]
In the above-described embodiment, absolute time information (first information) corresponding to the lead-in area A2C (first recording area) is written on the first disc-shaped recording medium, and the absolute time information is recorded. According to the description content of (first information), it is configured as a normal type optical disc to which digital audio data (second information) D3 can be written, and the second disc-shaped recording medium is set to absolute time information (first information). Absolute time information (third information) in which the description content of the absolute time information (first information) is changed without adding new types of elements different from the time code information and extra information (a plurality of elements) forming (Information) is described as a special type optical disc written in the lead-in area A2C (first recording area). However, the present invention is not limited to this. In short, if the special type optical disc does not add a new kind of elements to the normal type optical disc, the first and second disc-shaped recording media having various configurations can be widely applied. May be.
[0082]
Furthermore, in the above-described embodiment, the description content of the absolute time information (third information) corresponding to the lead-in area A2C (first recording area) in the special type optical disc as the second disc-shaped recording medium is Of the plurality of time code information and extra information (a plurality of elements) forming the absolute time information (first information) corresponding to the lead-in area A2C (first recording area) in the normal type optical disc, each extra information ( Although the case where the order of each element that is cyclically repeated) is set and changed is described, the present invention is not limited to this, and instead of or in addition to the order of each extra information, You may make it change the setting of the continuity of each said extra information.
[0083]
In this case, as the description content of the absolute time information (third information) corresponding to the lead-in area A2C in the special type optical disc, the arrangement order of the consecutive extra information in the absolute time information is changed from the normal type determination order to the special type determination. As an example of changing the setting to the order, the special information SI1, SI2, SI3 and the additional information AI1, AI2 are changed to the special information SI3, SI2, SI1, and the additional information AI2, AI1. As described above, the present invention is not limited to this. The extra information may be arranged in various arrangement orders other than the normal type discrimination order, and the setting may be changed to the special type discrimination order.
[0084]
Further, as a special type discrimination order different from the normal type discrimination order, a plurality of pieces of each extra information may be continuously arranged before the time code information for 9 frames. For example, the extra information for one frame arranged in the previous stage of each time code information for nine frames is continuously displayed in the order of special information SI1, SI1, SI2, SI2, SI3, SI3 and additional information AI1, AI1, AI2, AI2. You may make it arrange | position so that it may circulate to.
[0085]
Furthermore, only a specific piece of extra information among each piece of extra information may be continuously arranged in the preceding stage of each time code information for nine frames. For example, the extra information for one frame arranged in the preceding stage of each time code information for nine frames is made to continue only the special information SI1 in the order of the special information SI1, SI1, SI1, SI2, SI3 and the additional information AI1, AI2. You may arrange in.
[0086]
Furthermore, in the above-described embodiment, the absolute time is added without adding new types of elements different from the plurality of time code information and extra information (a plurality of elements) forming the absolute time information (first information). Special type optical disc (second disc-shaped recording medium) in which absolute time information (third information) obtained by changing the description content of information (first information) is written in lead-in area A2C (first recording region) Is loaded with the optical pickup 11, the RF amplifier 10 and the CPU 19 in the optical disc apparatus 1 to read the absolute time information (third information) from the lead-in area A2C of the special type optical disc. However, the present invention is not limited to this, and reading means having various configurations can be widely applied.
[0087]
Furthermore, in the above-described embodiment, based on the description content of the absolute time information (third information) read from the lead-in area A2C (first recording area) of the special type optical disc (second disc-shaped recording medium). In the above description, the discriminating means for discriminating whether or not the special type optical disc is loaded is constituted by the ATIP decoder 13 and the CPU 19 in the optical disc apparatus 1, but the present invention is not limited to this. Discriminating means having various other configurations can be widely applied.
[0088]
In this determination means, various setting information related to the special type optical disc may be recognized based on the description content of the absolute time information (third information). In this case, for example, the lower limit and upper limit of the writing speed of the optical disc 3 and the range thereof, the material of the optical disc 3, the manufacturer name, the lot number, etc. may be assigned as setting information.
[0089]
Furthermore, in the above-described embodiment, a plurality of times for forming absolute time information (first information) corresponding to the normal type optical disc as the description content of the absolute time information (third information) corresponding to the special type optical disc. The case where the memory means for sequentially storing the extra information (designated types of elements) among the code information and the extra information (a plurality of elements) is configured from the CPU 19 and the memory 30 in the optical disc apparatus has been described. The present invention is not limited to this, and memory means having various other configurations can be widely applied.
[0090]
Further, in the above-described embodiment, every time the extra information is stored in the memory (memory means) 30, the CPU 19 constituting this discrimination means raises the flag while raising the flag according to the extra information. The case where the order and / or continuity of each extra information is recognized according to the state or the falling state, and whether or not the special type optical disc is loaded is described based on the recognition result. The present invention is not limited to this, and if the order and continuity of the extra information can be recognized via the memory means, it is possible to recognize whether or not the special type optical disk is loaded by various methods.
[0091]
Further, in the above-described embodiment, the CPU 19 constituting this determination means predetermines the number of times of expression of each extra information (each element that is cyclically repeatedly expressed) stored in the memory (memory means) 30 for each type. After obtaining each unit, it may be determined whether or not a special type optical disc is loaded based on the result of code conversion.
[0092]
In this case, among the absolute time information (third information) corresponding to the lead-in area A2C, the number of times each extra information is expressed (number of times stored in the memory) is obtained by accumulating, for example, in units of 60 frames. At this time, “1” is set when the extra information for one frame is arranged in the preceding stage of each time code information for nine frames, and “0” is set when the time code information for all 10 frames is arranged. If the number of times each extra information is expressed in 60 frames is obtained, each extra information takes a numerical value from “0” to “5”. Therefore, if the five types of extra information are code-converted into, for example, special information SI1, SI2, SI3 and additional information AI1, AI2 in the order of 5 digits, various setting information is assigned to the 5 digits of the hexadecimal number. be able to.
[0093]
In this way, if the number of occurrences of each extra information (each element that is cyclically expressed repeatedly) is obtained for each type for each predetermined unit and each code is converted, the numerical values and symbols (such as alphabets) after the code conversion are very Thus, it is possible to allocate a large amount of setting information, and thus it is possible to efficiently increase the setting information using only existing information without newly increasing the type of information.
[0094]
Further, in the above-described embodiment, the CPU 19 that constitutes the discriminating means is based on the data length of each time code information (each element that forms time information) stored in the memory (memory means). It may be determined whether or not is loaded.
[0095]
In this case, the data length of each time code information is usually 9 frames. However, the time code is set to an arbitrarily set number of frames such as 5 frames, 10 frames or 15 frames following the extra information of 1 frame. Information should be arranged. For example, when the data length of the time code information is increased step by step by 5 frames or 10 frames, the start position of the lead-in area A2C may be shifted to be offset.
[0096]
In addition to this, the CPU 19 that constitutes the discriminating means has an array of extra information (other types of elements) that appears between the time code information (elements that form the time information) of which the data length is arbitrarily set. Based on the order, it may be determined whether or not a special type optical disk is loaded.
[0097]
Further, in the above-described embodiment, the CPU 19 that constitutes the discriminating unit performs special processing based on the address or time position of absolute time information (third information) corresponding to the lead-in area A2C (first recording area). It may be determined whether or not a type optical disc is loaded.
[0098]
That is, it may be determined that a special type optical disc is loaded when specific extra information exists at a fixed address (or time position) in the absolute time information (third information). In this case, for example, on the assumption that the special information SI1 exists at the fixed address (99:50:00) of the absolute time information (first information) corresponding to the normal type optical disc, the absolute time information corresponding to the special type optical disc The special information SI1 may be set to exist at the fixed address (99:50:01) of (third information).
[0099]
Further, in the above-described embodiment, the case where the lead-out area is applied as the second recording area different from the lead-in area A2C (first recording area) of the special type optical disk has been described. The present invention is not limited to this, and various kinds of extended information (for example, parameters according to the ultra high speed specific to the special type disc) necessary for writing the digital audio data (second information) may be written in other areas. The second information can be widely applied to various digital data other than the digital audio data D3.
[0100]
【The invention's effect】
As described above, according to the present invention, in the disc-shaped recording medium in which the first information is written in the first recording area and the second information can be written according to the description content of the first information, The third information can be obtained from the configuration of the plurality of elements without adding a new type of element different from the plurality of elements forming the information. In the description content of the third information, among the plurality of elements forming the first information, the order or continuity of each element that is cyclically repeatedly expressed is changed. As a result, new information is expanded and added to the contents of the lead-in area of the optical disc. Since the third information can be obtained by simply changing the order and continuity of the cyclically repeating elements among the elements forming the first information without doing so, It is possible to realize a disc-shaped recording medium that can efficiently use information within a limited area, and thus can significantly improve the use efficiency for the user.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an optical disc apparatus according to an embodiment.
FIG. 2 is a schematic diagram for explaining each area on a recording surface of an optical disc.
FIG. 3 is a schematic diagram for explaining the configuration of one block;
FIG. 4 is a schematic diagram for explaining the configuration of one frame.
FIG. 5 is a conceptual diagram for explaining the contents of subcode Q data;
FIG. 6 is a schematic diagram for explaining contents of a normal type discrimination order;
FIG. 7 is a schematic diagram for explaining contents of a special type discrimination order;
FIG. 8 is a flowchart for explaining a write setting processing procedure;
FIG. 9 is a flowchart for explaining a determination mode processing procedure;
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Optical disk apparatus, 2 ... Host computer, 3 ... Optical disk, 3A ... Recording surface, 11 ... Optical pick-up, 19 ... CPU, D3 ... Digital audio data (read-out data), DQ ... Subcode Q data, A1 ... Program area, A2 ... Subcode data area, A2A ... Power calibration area (PCA), A2B ... Program memory area (PMA), A2C ... Lead-in area, A2D ... Lead-out Area, R1... Write setting processing procedure, R2.

Claims (5)

In a disc-shaped recording medium in which the first information is written in the first recording area and the second information can be written according to the description content of the first information.
Without adding a new type of element different from the plurality of elements forming the first information, the third information can be obtained from the configuration of the plurality of elements,
The description content of the third information is a disc-shaped recording medium in which the order or continuity of each of the elements that are cyclically expressed among the plurality of elements forming the first information is changed. The disc-shaped recording medium according to claim 1, wherein various extended information necessary for writing the second information is written in a second recording area different from the first recording area. The disc-shaped recording according to claim 1, wherein the description content of the third information is set and changed in data length of each of the elements forming the absolute time information among the plurality of elements forming the first information. Medium. The disc-shaped recording medium according to claim 3, wherein the description content of the third information is a setting change of an arrangement order of the first information forming the absolute time information. The disc-shaped recording medium according to claim 1, wherein the description content of the third information is a setting change of an address or a time position of each of the elements forming the first information in the first recording area.

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