JP3839926B2 - Disc playback apparatus and disc playback method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an improvement in a disk reproducing apparatus and a disk reproducing method for reproducing an optical disk such as a DVD (Digital Video Disk).
[0002]
[Prior art]
As is well known, recently, a DVD has been developed as an optical disk in which an enormous amount of data of about 5 Gbits is recorded on one side, and a DVD playback apparatus for playing back this DVD has also become popular in the market.
[0003]
By the way, this DVD has a BCA (Burst Cutting Area) code by a YAG laser in a specific area inside the lead-in area, as shown in FIG. May be recorded.
[0004]
FIG. 6 shows the structure of such BCA data. First, the number of BCA user data has a variable information area of 16n−4 (1 ≦ n ≦ 12) bytes, and includes 4 bytes of EDC (Error Detection Code) parity and 16 bytes of ECC (Error Correction Code). ) Parity is added.
[0005]
Then, 1 byte of sync data RSBCAn is added to each 4 bytes of this variable information area and EDC parity, and 1 byte of sync data RSBCA13 is added to every 4 bytes of ECC parity.
[0006]
The BCA data has 1 byte of sync data SBBCA and 4 bytes of BCA-Preamble data, each of which is “00 (hexadecimal)”, added to the head thereof.
[0007]
Further, this BCA data is added with 1 byte of sync data RSBCA14 and 4 bytes of BCA-Postamble data, each of which is “55 (hexadecimal)”, after that ECC parity. Sync data RSBCA15 is added.
[0008]
Each sync data SBBCA, RSBCAn, RSBCA13, RSBCA14, and RSBCA15 is composed of 8 channel bits representing a specific sync pattern and 8 channel bits representing a frame number (n). Note that the modulation rule is such that 1 bit becomes 2 channel bits.
[0009]
Here, although the number of user data in one frame is 16 bytes, only in the nth frame, the number of user data is 12 bytes, and 4 bytes of EDC parity are added. For example, if n = 5, the number of user data is 16 × 5−4 = 76 bytes, and 4-byte EDC parity is added after the fourth row of sync data RSBCA5 in 5 frames.
[0010]
The 16-byte Reed-Solomon ECC parity added by interleaving in the vertical direction of the BCA data structure belongs to 13 frames regardless of the user data length. For example, if n = 5, the sync data RSBCA13 appears after the EDC parity of 5 frames, and the ECC parity follows.
[0011]
As described above, this BCA data is recorded with a sufficient width on a concentric circle on the inner periphery further than the lead-in area of the DVD. The shorter the data length, the more the BCA data in the BCA data recording area on the DVD. The data non-recording area is increased.
[0012]
In this BCA data modulation rule, two-channel bits “10” and “01” are assigned to 1-bit data representing “0” and “1”, respectively. The specific sync pattern is “01000110” from the top, and the subsequent frame number is obtained by modulating the 4-bit data representing “0” to “13” into 8 channel bits according to the modulation rule described above. Yes.
[0013]
According to this modulation rule, the minimum polarity inversion interval Tmin of data is 1T, and the maximum polarity inversion interval Tmax is 4T. However, according to the modulation rule, this 4T pattern appears only in the sync data.
[0014]
FIG. 7 shows a disc reproducing apparatus capable of reproducing such an optical disc on which BCA data is recorded. In FIG. 7, reference numeral 11 denotes an optical disk on which BCA data is recorded, and is rotated by a disk motor 12. Further, an optical pickup 13 is installed facing the signal recording surface of the optical disc 11.
[0015]
The rotational speed of the disk motor 12 is controlled by a servo circuit 14. The optical pickup 13 is subjected to tracking servo and focus servo for an objective lens (not shown) by a servo circuit 14 and the movement of the optical disk 11 in the radial direction is controlled.
[0016]
Here, when reproducing the BCA data of the optical disk 11, a control MPU (Micro-Processing Unit) 15 that comprehensively controls the operation of the disk reproducing apparatus is optimally adapted to reproduce the BCA data on the optical disk 11 by the servo circuit 14. A CAV (Constant Angular Velocity) servo is applied so as to keep the rotation speed at 24 Hz (1440 rpm), and the optical pickup 13 is moved to the BCA data recording area.
[0017]
Then, the electrical signal corresponding to the BCA data output from the optical pickup 13 is supplied to the data slice circuit 18 through the amplifier circuit 16 and the equalizer circuit 17 and binarized. This binarized signal is supplied to a BCA detection circuit 19 and a PLL (Phase Locked Loop) circuit 20.
[0018]
Among these, the PLL circuit 20 generates a channel bit clock from the input binarized signal and outputs it to the BCA detection circuit 19. The BCA detection circuit 19 extracts data from the input binarized signal based on the channel bit clock, and generates BCA detection channel bits.
[0019]
The BCA detection circuit 19 detects the sync pattern from the BCA data stream based on the channel bit clock and the BCA detection channel bit, and demodulates the subsequent 8 channel bit data to obtain the frame number. It has gained.
[0020]
Thereafter, the BCA detection circuit 19 generates an in-frame row number from 0 to 3 for the obtained frame number, determines an address for the BCA data storage memory 21, and sequentially stores the demodulated BCA data. . The BCA data storage memory 21 records 208 bytes when the BCA data is the longest, that is, when n = 12.
[0021]
The BCA data recorded in the BCA data storage memory 21 is subjected to error correction processing based on EDC parity and ECC parity by the BCA data processing circuit 22.
[0022]
FIG. 8 shows details of the BCA detection circuit 19. That is, the BCA binarized signal output from the data slicing circuit 18 is output to the data bus via the input terminal 19a, the demodulation circuit 19b, and the output terminal 19c. The channel bit clock output from the PLL circuit 20 is supplied to the demodulation circuit 19b and the sync detection circuit 19e via the input terminal 19d.
[0023]
The output of the demodulating circuit 19b and the output of the sync detecting circuit 19e are output to the address bus via the memory address generating circuit 19f and the output terminal 19g, and also via the BCA recording length detecting circuit 19h and the output terminal 19i. It is output to the BCA data processing circuit 22.
[0024]
Here, when the optical pickup 13 reaches the BCA data recording area from the data non-recording area of the optical disc 11, a channel bit starting from the sync data SBBCA is detected. Then, when the sync data SBBCA and BCA-Preamble data are reproduced, the PLL circuit 20 is locked and a normal channel bit clock can be obtained.
[0025]
At this time, the BCA detection circuit 19 first detects the sync pattern of the sync data RSBCA 1 and generates an address “0” in the BCA data storage memory 21. Thereafter, the BCA detection circuit 19 performs a data demodulation process for each detected 16 channel bit, which is 1 byte, and increments the address each time.
[0026]
In this way, when 4 bytes of data is recorded in the BCA data storage memory 21, the sync data RSBCA1 should be detected again. If the sync data RSBCA1 cannot be detected again, the BCA detection circuit 19 Assuming that sync data can be detected in a pseudo manner, so-called synchronization protection is performed without changing the data demodulation interval and the address increment.
[0027]
Further, the BCA detection circuit 19 sets a sync detection window of about ± 2 channel bit width for the predicted position where sync data is detected, and if sync data can be detected in this window, the position correction is performed. Correct subsequent data demodulation synchronization.
[0028]
If the sync data detected at this time is a value other than RSBCA1, such as RSBCA2 or RSBCA10, the BCA detection circuit 19 regards this as a detection error and does not change the address. I have to.
[0029]
When the 16-byte demodulated data is recorded in the BCA data storage memory 21, the next generated sync data should be RSBCA2 or RSBCA13. However, the BCA detection circuit 19 does not depend on the frame number. The address increment is continued and the data demodulation synchronization is continued without changing.
[0030]
That is, even if the data demodulation synchronization is changed by correcting the position of ± 2 channel bits by the sync data, the address is incremented continuously. When the address is generated in this way, the address for each byte of the user data, its EDC parity and ECC parity is generated as shown in FIG.
The data is demodulated and recorded by the above procedure, and the recording operation is terminated when 16 bytes of data to which the sync data RSBCA13 is added are recorded.
[0031]
[Problems to be solved by the invention]
However, in the conventional disk reproducing apparatus as described above, it is necessary to apply CAV servo to the optical disk 11 so as to maintain the optimum rotation speed (24 Hz) for reproducing the BCA data, and for the data extraction by the PLL circuit 20. It is necessary to generate the channel bit clock of Therefore, both the rotary servo and the PLL circuit have to add a BCA playback circuit to a normal DVD playback circuit, resulting in a problem that the circuit configuration becomes complicated and large, and the processing becomes complicated.
[0032]
Therefore, the present invention has been made in consideration of the above circumstances, and does not require complicated processing, and it is possible to reproduce BCA data from a disk with a simple configuration, and a very good disk reproduction apparatus and disk reproduction. It aims to provide a method.
[0033]
[Means for Solving the Problems]
The disc reproducing apparatus according to the present invention is intended for an apparatus that reproduces a disc on which second data by laser cutting is recorded in the vicinity of an area in which the first data is recorded.
[0034]
Then, in a state where the rotation servo is applied to the disk so that the rotation speed corresponds to the reproduction of the first data, the rotation servo is turned off, and a pickup for reading recorded data from the disk is provided. Control means for moving to the area where the second data is recorded;
Counting means for cyclically counting a clock having a constant period shorter than the channel bit period of the second data; and generating means for generating a window between the first count value and the second count value of the counting means; And having a predetermined width having a period corresponding to the channel bit period of the second data in a state where the rotation servo is turned off by the control means and the pickup reaches the area where the second data is recorded. Window generating means for generating a window;
This is to detect whether or not the edge of the second data read by the pickup is obtained within the window generation period by the window generating means, and the edge of the second data is obtained within the window generation period. In this state, the count value of the counting means is set to an intermediate value between the first and second count values to stop the generation of the window, generate the first detection value, and generate the first detection value within the window generation period. And detecting means for generating a second detection value after the generation of the window is stopped in a state in which the edge of the data 2 is not obtained .
[0035]
The disc reproducing method according to the present invention is directed to a method of reproducing a disc on which second data by laser cutting is recorded in the vicinity of an area in which the first data is recorded.
[0036]
Then, after performing the rotation servo so that the rotation speed corresponding to the reproduction of the first data is applied to the disk, the rotation servo is turned off, and a pickup for reading the recording data from the disk, A first step of moving to a region where the second data is recorded;
Counting means for cyclically counting a clock having a constant period shorter than the channel bit period of the second data; and generating means for generating a window between the first count value and the second count value of the counting means; And a predetermined width having a period corresponding to the channel bit period of the second data after the rotary servo is turned off by the first step and the pickup reaches the area where the second data is recorded. A second step of generating a window of
This is to detect whether or not the edge of the second data read by the pickup is obtained within the window generation period in the second step. The edge of the second data is obtained within the window generation period. In this state, the count value of the counting means is set to an intermediate value between the first and second count values to stop the generation of the window and generate the first detection value within the generation period of the window. A third step of generating a second detection value after the generation of the window is stopped in a state where the edge of the second data is not obtained .
[0037]
According to the configuration and method as described above, the rotational servo is applied to the disk so that the rotational speed corresponds to the reproduction of the first data, the rotational servo is turned off, and the pickup is moved to the second data recording area. Since the detection of whether or not the edge of the second data can be obtained in the window generated in the period predicted in advance, the generation of the channel bit clock for the rotation servo and data extraction as in the past is performed. Therefore, the second data can be reproduced from the disc with a simple configuration without requiring complicated processing.
[0038]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. 1, the same parts as those in FIG. 7 are denoted by the same reference numerals. That is, the PLL circuit 20 for generating the channel bit clock is deleted from the BCA binarized signal output from the data slicing circuit 18, and instead, a circuit as shown in FIG. I have to prepare.
[0039]
In FIG. 2, reference numeral 23 denotes a channel bit measurement counter that measures the expected value of the BCA channel bit 1T width by counting a crystal clock having a constant frequency supplied to the clock input terminal 24. As shown in FIG. 3, the BCA channel bit has a 1T width of 8.89 ± 2 μs when the rotation frequency of the optical disk 11 is 24 Hz, and a 4T width of 8.89 × 4 ± 2 μs.
[0040]
Therefore, when the frequency of the crystal clock counted by the channel bit measurement counter 23 is 26 MHz, for example, the conversion is such that 179 to 284 clocks are included in the 1T width and 872 to 977 clocks are included in the 4T width. The expected 1T width value is set to 232 clocks at the center, and the channel bit detection window width W is set to 128 clock widths so as to follow fluctuations in the bit period from 1T to 4T.
[0041]
Here, in actually reproducing the BCA data, the control MPU 15 issues a command to the servo circuit 14 so as to reproduce the lead-in area of the optical disk 11 by the CLV (Constant Linear Velocity) method. At the time when the rotation of the optical disk 11 is stabilized (the rotation speed of the optical disk 11 at this time is close to 24 Hz suitable for reproducing the BCA data recording area), the control MPU 15 14, the rotation control of the disk motor 12 is turned off, and a command is issued to move the optical pickup 13 to the BCA data recording area of the optical disk 11.
[0042]
In this case, the rotational speed of the optical disk 11 is automatically decelerated by turning off the rotational control of the disk motor 12, but it takes several seconds until the rotational speed of the optical disk 11 is greatly reduced from 24 Hz. Therefore, the rotation speed of the optical disk 11 is sufficiently maintained in the vicinity of 24 Hz if the time is about 2 to 3 rotations necessary for reading the BCA data.
[0043]
Thereafter, the control MPU 15 issues a command to the BCA detection circuit 19 so as to start detection of BCA data. In response to this instruction, the counter control circuit 25 of the BCA detection circuit 19 opens the channel bit detection window.
[0044]
On the other hand, the BCA binarized signal output from the data slice circuit 18 is supplied to the channel bit edge detection circuit 27 via the input terminal 26. The channel bit edge detection circuit 27 detects a BCA channel bit of the input BCA binary signal, that is, a falling edge, and outputs the detection signal to the counter control circuit 25.
[0045]
Then, when the detection signal is supplied from the channel bit edge detection circuit 27 in the open state of the channel bit detection window, the counter control circuit 25 supplies the channel bit detection window width W to the channel bit measurement counter 23. A value half of (here 128) is set, and the count-up is started from the set value.
[0046]
At this time, the counter control circuit 25 closes the channel bit detection window, and when the count value of the channel bit measurement counter 23 matches T (here, 232), the count value of the channel bit measurement counter 23 Is reset to 0.
[0047]
Thereafter, the counter control circuit 25 opens the channel bit detection window when the count value of the channel bit measurement counter 23 is between 0 and W, and when the falling edge of the BCA data is detected, the channel bit measurement counter 23 Is set to W / 2 to close the channel bit detection window, and at this time, the BCA channel bit detection value 1 is output to the demodulation circuit 28.
[0048]
Further, the counter control circuit 25 determines the channel bit before the count value of the channel bit measurement counter 23 reaches W, that is, when the falling edge of the BCA data is not detected in the open state of the channel bit detection window. The detection window is closed, and at this time, the BCA channel bit detection value 0 is output to the demodulation circuit 28.
[0049]
4A to 4E show the above operations in waveforms. That is, FIG. 4A shows a signal corresponding to the BCA data detection command and indicates that BCA data detection is requested by inverting from the L (Low) level to the H (High) level. FIG. 4B shows BCA data supplied to the input terminal 26.
[0050]
Further, FIG. 4C shows the count value of the channel bit measurement counter 23. The channel bit measurement counter 23 basically counts from 0 to T (in this case, 232), and the count value is W / 2 at the fall of the BCA data shown in FIG. Is set to
[0051]
FIG. 4D shows a channel bit detection window. The channel bit detection window is in the H level open state when the count value of the channel bit measurement counter 23 is 0 to W, but is in the L level closed state at the fall of the BCA data.
[0052]
FIG. 4E shows the detected value of the BCA channel bit. This BCA channel bit detection value is 1 when the fall of the BCA data is detected within the open period of the channel bit detection window, and the fall of the BCA data is not detected within the open period of the channel bit detection window. 0 in some cases.
[0053]
When the state where the falling edge of the BCA data is not detected within the open period of the channel bit detection window occurs a predetermined number of times or more, the channel bit detection window is unconditionally opened and returned to the initial state. It has become. Then, based on the channel bit detection value thus obtained, sync data is detected, BCA data is demodulated, an address is generated, and recorded in the BCA data storage memory 21 as in the prior art.
[0054]
According to the embodiment described above, the lead-in area of the optical disk 11 is reproduced by the CLV method, and when the rotation speed of the optical disk 11 is stabilized, the rotation servo for the optical disk 11 is turned off and the optical pickup 13 is turned on. By moving to the BCA data recording area and opening the channel bit detection window at a period predicted in advance, the BCA channel bits are detected and the BCA data is reproduced.
[0055]
For this reason, the CAV servo is not required as in the prior art, and it is not necessary to generate a channel bit clock for data extraction. Therefore, no complicated processing is required, and BCA data can be read from the optical disk 11 with a simple configuration. Will be able to play.
[0056]
In addition, since the center position of the channel bit detection window is adjusted with crystal accuracy every time the channel bit is detected, it is possible to easily follow the period variation due to the roughness of cut accuracy peculiar to BCA. Become.
The present invention is not limited to the above-described embodiment, and can be variously modified and implemented without departing from the scope of the invention.
[0057]
【The invention's effect】
As described above in detail, according to the present invention, there is provided a very good disc reproducing apparatus and disc reproducing method capable of reproducing BCA data from a disc with a simple configuration without requiring complicated processing. be able to.
[Brief description of the drawings]
FIG. 1 is a block configuration diagram showing an embodiment of a disk reproducing apparatus according to the present invention.
FIG. 2 is a block configuration diagram showing details of a main part in the embodiment.
FIG. 3 shows a BCA data waveform in the same embodiment.
FIG. 4 is a diagram showing a waveform of each part in the embodiment.
FIG. 5 is a plan view for explaining a recording area of BCA data on an optical disc.
FIG. 6 is a view for explaining the format of the BCA data.
FIG. 7 is a block diagram showing a conventional disc reproducing apparatus for reproducing the BCA data.
FIG. 8 is a block configuration diagram showing details of a main part of the disc playback apparatus.
FIG. 9 is a diagram showing an example of address generation in the disc playback apparatus.
[Explanation of symbols]
11 ... Optical disc,
12 ... disk motor,
13: Optical pickup,
14 ... Servo circuit,
15 ... Control MPU,
16 ... amplifier circuit,
17 ... Equalizer circuit,
18: Data slice circuit,
19 ... BCA detection circuit,
20 ... PLL circuit,
21 ... BCA data storage memory,
22 ... BCA data processing circuit,
23: Counter for channel bit measurement,
24: Clock input terminal,
25. Counter control circuit,
26: Input terminal,
27: Channel bit edge detection circuit,
28: Demodulation circuit.

Claims (4)

In a disc reproducing apparatus for reproducing a disc on which second data by laser cutting is recorded in the vicinity of an area where first data is recorded,
With the rotation servo applied to the disk so that the rotation speed corresponds to the reproduction of the first data, the rotation servo is turned off, and a pickup for reading recorded data from the disk is provided. Control means for moving to the area where the second data is recorded;
Counting means for cyclically counting a clock having a constant period shorter than the channel bit period of the second data, and generating means for generating a window between the first count value and the second count value of the counting means The rotation servo is turned off by the control means, and the pickup corresponds to the channel bit period of the second data in a state where the pickup has reached the area where the second data is recorded. a window generation means for generating said window of predetermined width having a period,
It is detected whether the edge of the second data read by the pickup is obtained within the window generation period by the window generation means, and the second data is detected within the window generation period. With the edge obtained, the count value of the counting means is set to an intermediate value between the first and second count values to stop the generation of the window and generate the first detection value, And detecting means for generating a second detection value after the generation of the window is stopped in a state where an edge of the second data is not obtained within the generation period of the window. Disc playback device. The area where the first data is recorded is a lead-in area, and the second data is BCA data recorded further on the inner periphery side than the lead-in area. 1 Symbol placement of the disk reproducing apparatus. In a disc reproducing method for reproducing a disc on which second data by laser cutting is recorded in the vicinity of an area where first data is recorded,
After the rotation servo is applied to the disk so that the rotation speed corresponds to the reproduction of the first data, the rotation servo is turned off and a pickup for reading recorded data from the disk is provided. A first step of moving to the area where the second data is recorded;
Counting means for cyclically counting a clock having a constant period shorter than the channel bit period of the second data, and generating means for generating a window between the first count value and the second count value of the counting means with the door, by said first step, said rotation servo is turned off, and, after the pickup has reached the recorded area of the second data, corresponding to a channel bit period of said second data a second step of generating said window of predetermined width with the period,
It is detected whether an edge of the second data read by the pickup is obtained within the window generation period in the second step, and the second data is detected within the window generation period. In the state where the edge is obtained, the count value of the counting means is set to an intermediate value between the first and second count values to stop the generation of the window and generate the first detection value. And a third step of generating a second detection value after the generation of the window is stopped in a state where the edge of the second data is not obtained within the generation period of the window. A disc playback method. The area where the first data is recorded is a lead-in area, and the second data is BCA data recorded further on the inner periphery side than the lead-in area. 3 Symbol mounting disk playback method of.

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