JP3632911B2 - Optical disc system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical information recording carrier and an optical information recording method for reading information by irradiating a converged light beam, and an optical information recording apparatus and an optical information reproducing apparatus using them.
[0002]
[Prior art]
In recent years, a read-only optical information record carrier (hereinafter referred to as a record carrier) holds important data as a medium for various information data such as audio information data and video information data because it can hold and reproduce large volumes of data. Is taking over. There is a need to further increase the capacity of the record carrier or to reduce the size of the optical information reproducing apparatus using the record carrier. In order to satisfy these requirements, it is necessary to further improve the recording density of information on the record carrier. There is.
[0003]
In a conventional record carrier, information tracks (hereinafter simply referred to as tracks) formed of pits are formed in a spiral shape or a concentric shape on the surface of a disk-shaped resin substrate. Further, a reflective film made of aluminum or the like is provided on the surface of the substrate on which the track is provided (referred to as an information carrier surface) by a technique such as sputtering. In the following description, even a single spiral track is treated as a plurality of tracks for the sake of simplicity when referring to portions at different radial positions from the center of the record carrier.
[0004]
In order to reproduce information from this type of record carrier, the record carrier is irradiated with a light beam generated from a semiconductor laser and converged on the information carrier surface. Reflected light from the record carrier is detected while performing tracking control for controlling the light beam on the record carrier to be positioned on the track. Since the amount of reflected light varies depending on the pits formed corresponding to information on the record carrier, the recorded information is read by detecting the change in the amount of light.
[0005]
As a control signal for tracking control, that is, a method for detecting a track shift signal corresponding to a positional shift (referred to as track shift) between a light beam on a record carrier and a track, a phase difference method and a three beam method are known.
[0006]
Among these, the phase difference method is a method in which the light reflected from the record carrier is received by a photodetector arranged in four crosses along the track direction and the track width direction on the detection surface, and the output of the opposite detector is detected. A track shift signal is detected from the phase difference of the sum signal. The phase difference method is disclosed in, for example, Japanese Patent Laid-Open Nos. 52-93222 and 62-20145.
[0007]
In the three-beam method, a total of three light beams including a reading beam and two auxiliary beams are irradiated onto the record carrier, and reflected light from the record carrier is detected by a photodetector. Then, a track shift signal is detected from the difference in the amount of reflected light between the two auxiliary beams. The 3-beam method is disclosed in, for example, Japanese Patent Publication No. 53-13123.
[0008]
[Problems to be solved by the invention]
The information recording density on the record carrier is determined by the track pitch and the information density in the track direction (that is, the information linear density). However, if the track pitch is narrowed, crosstalk from adjacent tracks increases. In particular, if there is a strong correlation between a signal recorded on a track and a signal recorded on an adjacent track, a pseudo signal is generated in the track deviation signal, and tracking control is not stable. Sometimes. For example, when pits are recorded over several tracks at the same spatial frequency, there is a correlation between the signal of the track where the light beam is located and the signal recorded on both adjacent tracks. It becomes very strong, and the track deviation signal is disturbed by the crosstalk from the adjacent track, and the tracking control becomes unstable.
[0009]
Considering the case of recording a digital image on a record carrier, information to be recorded includes a still image and a moving image. In the case of recording a moving image, no problem occurs because the recorded information changes with time. However, when recording a still image, the same image (same information) may be recorded over several tracks. In this case, signals having a strong correlation with each other are recorded between adjacent tracks, and tracking control becomes unstable there.
[0010]
Considering the case of recording data of a computer or the like, a track for several rounds of the outer circumference or inner circumference of the record carrier is generally used as a control area. The control data recorded in the control area includes information relating to the recording content of the record carrier. In this control area, data such as “FF” is uniformly recorded in an empty area where no information is recorded, for example, in hexadecimal display. In this case as well, the same information may be recorded over several tracks, and signals that are highly correlated with each other are recorded between adjacent tracks, and tracking control becomes unstable at that point.
[0011]
The control band of tracking control is generally about several kHz. If there is a highly correlated place in this control band, tracking control is disturbed there. For example, when the rotation speed of the record carrier is 1800 rpm, tracking control is disturbed if there is a place having a strong correlation over several mm at a position where the radius is 35 mm.
[0012]
The present invention has been made to solve the above-described problems, and an object of the present invention is to provide an optical information recording carrier, an optical information recording method, and an optical information recording method capable of obtaining a good track deviation signal even when the track pitch is narrowed. An optical information recording apparatus and an optical information reproducing apparatus are provided.
[0013]
[Means for Solving the Problems]
The optical information record carrier of the present invention is a disc-shaped optical information record carrier having spiral tracks composed of continuously arranged sectors, the sector being a continuous information for identifying a position. A sector number and data, and the data in the sector has a value that can be changed corresponding to a value of n or more lower bits (n is an integer of 2 or more) of the value indicating the sector number in binary number. This is data obtained as a result of being scrambled by a scrambled data string as an initial value, and thereby the above object is achieved.
[0014]
n is 2 ⁿ Can be an integer greater than or equal to 2 smaller than the number of sectors per circumference of the innermost track.
[0015]
The optical information recording method of the present invention is an optical information recording method for recording a continuous sector number and data for identifying the position of the sector in a spiral unit on a disk-shaped substrate. The method is based on a scrambled data sequence whose initial value is a value that can be changed corresponding to a value of n bits or more of the binary value of the sector number (n is an integer of 2 or more). A scramble process for scrambling data to be recorded therein, and a record process for recording the scrambled information, thereby achieving the above object.
[0016]
n is 2 ⁿ Can be an integer greater than or equal to 2 smaller than the number of sectors per circumference of the innermost track.
[0017]
The optical information recording apparatus of the present invention is an optical information recording apparatus that records a continuous sector number and data for identifying the position of the sector in a spiral unit on a disk-shaped substrate. The apparatus includes an initial value generating means for generating a value that changes in accordance with a value of n bits or more of the binary value of the sector number to be recorded (n is an integer of 2 or more), and the initial value generation A scramble data sequence generating means for generating a scramble data sequence having the value from the means as an initial value, and a scramble for scrambling data to be recorded in the sector using the scramble data sequence from the scramble data sequence generation means Means and recording means for recording data from the scramble means, whereby the above object is achieved.
[0018]
n is 2 ⁿ Can be an integer greater than or equal to 2 smaller than the number of sectors per circumference of the innermost track.
[0019]
An optical information recording apparatus according to another aspect of the present invention is an optical information recording apparatus that records information in units of sectors in a spiral or concentric manner on a disk-shaped substrate, and the apparatus records the information. An initial value generating means for generating a value corresponding to the value of identification information for identifying the position of the sector; and a scramble data string generating means for generating a scramble data string having the value from the initial value generating means as an initial value; Scramble means for scrambling data to be recorded in the sector using the scramble data string from the scramble data string generation means; and error correction by adding parity data to the identification information and the scrambled data An error correction code generating means for converting into a possible code word, and a recording means for recording the code word converted by the error correction code generating means. Ri, the above-mentioned object can be achieved by it.
[0020]
The initial value may be changed for every predetermined number of sectors that are continuous in the circumferential direction.
[0021]
The initial value is 2 ⁿ It can be changed for each sector (n is a positive integer).
[0022]
The initial value may be changed for each number of sectors smaller than the number of sectors per one turn of the innermost track.
[0023]
An optical information recording apparatus according to still another aspect of the present invention is an optical information recording apparatus that records information in units of sectors on a disk-like substrate in a spiral shape or a concentric circle shape. Initial value generating means for generating a value corresponding to the value of the identification information for identifying the position of the sector, and scramble data string generating means for generating a scramble data string having the value from the initial value generating means as an initial value And scramble means for scrambling data to be recorded in the sector using the scrambled data string from the scramble data string generation means, and a recording means for recording data from the scramble means, The initial value is changed for each of a smaller number of sectors than the number of sectors per track of the innermost track, thereby achieving the above object.
[0024]
The optical information reproducing apparatus of the present invention is an optical information reproducing apparatus for reproducing information recorded on a disk-shaped optical information recording carrier having spiral tracks composed of continuously arranged sectors. In this sector, a continuous sector number and information scrambled based on an initial value corresponding to the value of the sector number are recorded, and the apparatus reads from the optical information record carrier. Demodulating means for demodulating the regenerated reproduced signal to generate a demodulated signal, sector number reading means for reading the sector number from the demodulated signal, and a value of lower n bits or more of the binary value of the read sector number ( n is an integer greater than or equal to 2), and an initial value generating means for generating a descrambling data string for generating a descrambling data string having the value from the initial value generating means as an initial value. And descrambling means for descrambling the demodulated data from the demodulating means using the descrambling data string from the descrambling data string generating means, whereby the above object is achieved. The
[0025]
n is 2 ⁿ Can be an integer greater than or equal to 2 smaller than the number of sectors per circumference of the innermost track.
[0026]
An optical information recording carrier provided by still another aspect of the present invention includes an optical information comprising a disk-shaped substrate and at least one track formed spirally or concentrically on the surface of the substrate. A record carrier, wherein the track includes a plurality of consecutively arranged sectors, and in the plurality of sectors, information scrambled based on an initial value corresponding to a value of identification information for identifying a sector position is stored. Recorded, which achieves the above objectives.
[0027]
In one embodiment, the track is formed in a spiral shape, and each of the plurality of sectors included in the track is assigned a continuous sector number for identifying the sector position, and the sector number is Used as the identification information.
[0028]
In another embodiment, the initial value is changed for each predetermined number of sectors that are continuous in the circumferential direction.
[0029]
In still another embodiment, the initial value is 2 ⁿ It is changed for each sector (n is a positive integer).
[0030]
In yet another embodiment, the initial value is changed for each of a smaller number of sectors than the number of sectors per round of the innermost track.
[0031]
An optical information recording method provided by still another aspect of the present invention is an optical information recording method for recording information on at least one track formed in a spiral shape or a concentric shape on the surface of a disk-shaped substrate. The track includes a plurality of consecutively arranged sectors, and the method includes a scrambling step of scrambling information based on an initial value corresponding to a value of identification information for identifying a sector position, and the plurality of sectors. And the recording step of recording the scrambled information, thereby achieving the above object.
[0032]
In one embodiment, the track is formed in a spiral shape, and each of the plurality of sectors included in the track is given a continuous sector number for identifying the sector position, and the sector number is included in the sector number. The information is scrambled based on a shift register series having a corresponding value as an initial value.
[0033]
In another embodiment, the initial value is changed for each predetermined number of sectors that are continuous in the circumferential direction.
[0034]
In still another embodiment, the initial value is 2 ⁿ It is changed for each sector (n is a positive integer).
[0035]
In yet another embodiment, the initial value is changed for each of a smaller number of sectors than the number of sectors per round of the innermost track.
[0036]
In still another embodiment, the scrambling step includes a step of dividing the information corresponding to the plurality of sectors, and each of the divided information is based on the initial value according to the value of the identification information. And scrambling the identification information and the scrambled information into an error-correctable codeword. In the recording step, the information converted into the codeword includes the plurality of information It is recorded in each sector.
[0037]
In still another embodiment, the scrambling step includes the step of dividing the information corresponding to the plurality of sectors, and the step of converting the identification information and the divided information into a codeword capable of error correction. Scramble each of the codewords based on the initial value according to the value of the identification information, and in the recording step, the information is stored in the form of the scrambled codeword. Is recorded in each of the sectors.
[0038]
An optical information reproducing device provided by still another aspect of the present invention is recorded on an optical information recording carrier comprising at least one track formed in a spiral shape or concentric shape on the surface of a disc-like substrate. An optical recording / reproducing apparatus for reproducing information, wherein the track includes a plurality of consecutively arranged sectors, and the information corresponds to a value of identification information for identifying a sector position in the plurality of sectors. The apparatus is recorded in a scrambled format based on an initial value, and the apparatus demodulates a reproduction signal reproduced from the optical record carrier to generate a demodulation signal, and the identification information from the demodulation signal Identification information reading means for reading out, initial value generating means for generating a value corresponding to the identification information read by the identification information reading means, and descrambling based on the demodulated signal A timing signal generating means for generating a timing signal indicating a start timing; and a descrambling code for generating a code for descrambling using the value generated by the initial value generating means as the initial value in response to the timing signal A generator and descrambling means for descrambling the demodulated signal based on a code generated by the descrambling code generator are provided, whereby the above object is achieved.
[0039]
An optical information reproducing device provided by still another aspect of the present invention is recorded on an optical information recording carrier comprising at least one track formed in a spiral shape or concentric shape on the surface of a disc-like substrate. An optical recording / reproducing apparatus for reproducing information, wherein the track includes a plurality of consecutively arranged sectors, and the information corresponds to a value of identification information for identifying a sector position in the plurality of sectors. The apparatus is recorded in a scrambled format based on an initial value, and the apparatus demodulates a reproduction signal reproduced from the optical record carrier to generate a demodulation signal, and an error included in the demodulation signal Error correction means for correcting the error and generating corrected information, identification information reading means for reading the identification information from the corrected information, and the identification information read by the identification information reading means Initial value generating means for generating a value corresponding to the timing information, timing signal generating means for generating a timing signal indicating the timing for starting descrambling based on the corrected information, and the initial value in response to the timing signal A descrambling code generator for generating a code for descrambling using the value generated by the generating means as the initial value, and a descrambling for descrambling the corrected information based on the code generated by the descrambling code generator Means for achieving the above object.
[0040]
The operation of the present invention will be described below.
[0041]
In the optical information recording carrier, the optical information recording method, the optical information recording apparatus, and the optical information reproducing apparatus of the present invention, the optical information recording carrier is included in at least a track formed in a spiral shape or a concentric shape on the surface of the disc-shaped substrate. Information scrambled based on an initial value corresponding to the value of identification information for identifying the sector position is recorded in a plurality of sectors. As a result, the data scrambled and randomized is recorded on the record carrier. Since different data is recorded between adjacent tracks, signal correlation between them is reduced. For this reason, the influence of the crosstalk is randomized and the influence on the track deviation signal is reduced, and stable tracking control can be performed even if the track pitch is narrowed.
[0042]
As identification information used when information is scrambled, for example, sector numbers assigned to a plurality of sectors can be used. Since the sector number is inevitably necessary for data recording, it can be easily used as identification information. Further, there is no need to provide a circuit for generating identification information.
[0043]
If the initial value at the time of scramble is changed for each predetermined number of sectors in the circumferential direction, even if data of the same content is continuously recorded, the scrambled and randomized data is stored on the record carrier. To be recorded.
[0044]
The initial value is 2 ⁿ If it is changed for each sector (n is a positive integer), the configuration of the initial value generating circuit can be simplified.
[0045]
If the initial value is changed for each number of sectors smaller than the number of sectors per track of the innermost track, even if information of the same content is continuously recorded in the innermost track, The recorded data is reliably randomized.
[0046]
When recording scrambled information, the information is first divided into a plurality of sectors, each of the divided information is scrambled based on an initial value corresponding to the value of the identification information, and then scrambled with the identification information. The information may be converted into a codeword that can be error-corrected. In this case, information converted into a code word is recorded in each of a plurality of sectors. As a result, when reading information from the optical information record carrier, the address is read after performing error correction, so the time required for reading the address is slightly longer, but even if an error occurs in the information due to dropout, etc. Will be corrected. Therefore, the address can be read with extremely high reliability and can be descrambled reliably.
[0047]
Alternatively, when recording the scrambled information, the information was divided into a plurality of sectors, and then the identification information and the divided information were converted into error-correctable codewords prior to the scramble process. A portion of the code word excluding the identification information may be scrambled based on an initial value corresponding to the value of each identification information. As a result, when reading information from the optical information record carrier, the address can be read only by performing demodulation, so that a high-speed search can be performed, and a large-capacity memory is not required to read the address.
[0048]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment)
The first embodiment of the present invention will be described below with reference to FIGS.
[0049]
FIG. 1 is a schematic plan view of a record carrier of the present invention. On the surface of the disc-shaped record carrier 101, a track 102 in which information is recorded in the form of pits is provided in a spiral shape. Information is recorded by a CLV (Constant Linear Velocity) method in which the information density per unit length on the track 102, that is, the linear density is constant regardless of the radial position on the record carrier 101. As described above, even if one spiral track is used, when referring to a portion at a different radial position from the center of the record carrier, it is handled as a plurality of tracks for the sake of simplicity. .
[0050]
The format of information recorded on the track 102 on the record carrier 101 will be described in detail with reference to FIGS.
[0051]
FIG. 2A is a track format diagram. The track 102 includes a plurality of sectors (S) each recording information in the same format. ₁ , S ₂ , S ₃ , ..., S _n , S _{n + 1} , ...) are formed continuously.
[0052]
FIG. 2B shows one sector (for example, the first sector S). ₁ ) Format. One sector is composed of 60 frames FR01 to FR60. Each frame has a resync mark area RS01 to RS60 for frame synchronization during reproduction, a frame address area FA01 to FA60 for identifying a frame position, and an information area INF01. To INF60 and postamble areas PA01 to PA60. The capacities of the resync mark areas RS01 to RS60 and the frame address areas FA01 to FA60 are all 1B (bytes) in terms of data in the information areas INF01 to INF60. Each capacity of the information areas INF01 to INF60 is 40B.
Although many pits may be provided in the postamble areas PA01 to PA60, typically one or two pits are formed. For example, when information is recorded by the RLL (1, 7) modulation method (coding which converts 8-bit data into 12 channel bits) known as a run length limited code, if the channel clock is T, the pit Or the space interval between pits is 2T to 11T. However, at least one combination of pits and spaces each having a length of 2T may be provided in the postamble areas PA01 to PA60.
[0053]
Alternatively, the pits in the postamble areas PA01 to PA60 are for facilitating reading of the information recorded in the information areas INF01 to INF60, so that the formation thereof can be omitted.
[0054]
The pits formed in the resync mark areas RS01 to RS60 are formed in a pattern that does not appear in other areas included in the frame. For example, in the case of the RLL (1, 7) modulation method described above, it is determined in advance so that pits are formed at intervals of 12T or more.
[0055]
FIG. 2C shows the format of one information area, for example, the information area INF01 of the first frame FR01. In the information area INF01 of the first frame FR01 having an information capacity of 40B, as shown in FIG. 2C, a sector address area 10 for recording a 16B sector address (header) for identifying the position of the sector, A 16B sub-code area 20 in which management information is recorded and a data area 30 in which 8B user data are recorded are provided.
[0056]
FIG. 2D shows the format of the sector address area 10. The sector address area 10 is further divided into a first area 10a and a second area 10b, and an address number ID0 or ID1 to which a CRC code is assigned is recorded. That is, the address number is recorded in duplicate in the first and second areas 10 a and 10 b of the sector address area 10. Specifically, a sector number assigned continuously from the inner periphery to the outer periphery is used as the address number.
[0057]
Of the information area INF01 of the first frame FR01, the data area 30 for 8B excluding the sector address (header) area 10 and the subcode area 20 and the information areas INF02 to INF60 of the second to 60th frames FR02 to FR60 are recorded. The information is scrambled to randomize the data, as will be described in detail later. In FIG. 2B, the regions to be scrambled are indicated as X1 to X60.
[0058]
FIG. 3 schematically shows the outline of an arrangement pattern of information of 2400B (40B × 60 frames per frame) recorded in one sector as an error correction code (hereinafter referred to as ECC) after a parity area is added. Indicate.
[0059]
The capacity of original data recorded in one sector is a total 2080B obtained by adding the sector address 16B and the subcode 16B to the user data 2048B. Here, “original data” means data before being converted into codewords. These data are interleaved in units of 1B (1B is 8 bits) and arranged in the original data area 40 in a pattern in the row direction 104B and the column direction 20B. Specifically, in FIG. 3, the original data is sequentially arranged in the sub areas 40-1 to 40-104 indicated by solid lines in the original data area 40.
[0060]
A parity area 50 is added to the data in the original data area 40 arranged in this way as follows. That is, in FIG. 3, for each of the sub-areas 40a to 40t indicated by dotted lines in the original data area 40, 16B inspection points are set for 104B information points constituting the sub-area (for example, 40a). Give. That is, an ECC having a code length of 120B, an inspection point of 16B, and an information point of 104B is formed. In FIG. 3, the check points assigned to the respective sub-regions 40 a to 40 t are shown as sub-regions 50 a to 50 t indicated by dotted lines in the parity region 50. As a result, the parity area 50 of 320B is added to the original data 2048B corresponding to the original data area 40 to form the codeword area 60, and the capacity of the information area of one sector becomes 2400B in total. The correction code configured as described above is a kind of Reed-Solomon code and is called LDC (Long Distance Code with a degree of redundancy of 16) having a redundancy of 16.
[0061]
The order in which information of one sector is recorded will be described with reference to FIG. FIG. 4 schematically shows the format of the record data recorded on the record carrier 101.
[0062]
Taking the first frame FR01 as an example, the resync mark area RS01, the frame address area FA01, the information area INF01, and the postamble area PA01 are arranged in this order in the direction of the arrow 401 in FIG. As described above, the 16B sector address, the 16B subcode, and the 8B user data are arranged in the information area INF01.
[0063]
Each frame is composed of two columns. The first column of the two columns corresponding to the first frame FR01 includes the resync mark area RS01, the frame address area FA01, and the information area INF01 of 40B in total. 4B of the sector address area 10 and the subcode area 20 are arranged. Of the two columns corresponding to the first frame, the remaining 12B of the subcode region 20, the user data region 30, and the postamble region PA01 are arranged in the second column.
[0064]
Hereinafter, the information of the second to 60th frames FR02 to FR60 is also recorded on the record carrier 101 in the same pattern. However, there is no sector address area 10 and subcode area 20 in the information areas INF02 to INF60 of the second to 60th frames FR02 to FR60, and all user data is recorded.
[0065]
Further, as described with reference to FIG. 3, the information actually recorded on the record carrier is the original data 2080B, and the parity area check point data 320B added thereto. In the example shown in FIG. 4, the first to 52nd frames FR01 to FR52 record original data corresponding to the original data area 40 of FIG. On the other hand, the 53rd to 60th frames FR53 to FR60 correspond to the parity area 50 of FIG.
[0066]
Information recording will be described with reference to FIG. FIG. 5 is a block diagram of a formatter device 500 that creates record data to be recorded on the record carrier 101.
[0067]
User data is sent to the address assignment circuit 502 from a user data sending device 501 such as a magnetic disk. The address assigning circuit 502 divides the received user data into 2048B, assigns the sector address and subcode information 32B to the head of each, and sends it to the ECC conversion circuit 503. The ECC conversion circuit 503 arranges the sent data as shown in FIG. 3 and converts it into a code word. Then, the data is sequentially transferred to the scramble circuit 504 from the top of the first column (left side in FIG. 4) of the converted codeword pattern. The scramble circuit 504 scrambles the data to randomize the data. The scramble circuit 504 scrambles the data excluding the sector address and 32B corresponding to the subcode and sends the scrambled data to the modulation circuit 505. The modulation circuit 505 modulates data by a predetermined modulation method and sends the data to the frame formatter circuit 506. The frame formatter circuit 506 divides incoming data into units of 40B, adds a resync pattern and a frame address to the head, and adds a postamble signal to the end of each to complete the recording data format. To do. The completed recording data is sent to a recording device (not shown).
[0068]
The recording apparatus rotates the master on which the photoresist layer is provided at a rotational speed that is inversely proportional to the radial position so that the linear velocity is constant. Then, the intensity of a light beam generated from a light source such as an argon laser or a krypton laser is modulated in accordance with a signal from the frame formatter circuit 506. By irradiating a rotating master with a modulated light beam, pits having a pattern corresponding to the signal are formed, and information is recorded. The recording apparatus is well known, and detailed description thereof is omitted.
The configuration of the scramble circuit 504 will be described with reference to the block diagram of FIG.
[0069]
The scramble circuit 504 includes an address reading circuit 601, an initial value generation circuit 602, an M series generator 603, a counting circuit 604, and an exclusive OR circuit (sum circuit modulo 2) 605.
[0070]
The address reading circuit 601 reads the sector address number from the data sent from the ECC conversion circuit 503 and sends the read address number to the initial value generation circuit 602. This address number is used as identification information during scrambling. The initial value generation circuit 602 generates an initial value corresponding to the received address number and sends it to the M-sequence generator 603. The exclusive OR circuit 605 sequentially outputs signals in accordance with the exclusive OR of the signal from the ECC conversion circuit 503 and the signal from the M-sequence generator 603.
[0071]
The counting circuit 604 measures the amount of data sent from the ECC conversion circuit 503, and generates a scramble operation start signal when transmission of 32B of information from the head of the sector is completed. Send to M-sequence generator 603. That is, the counting circuit 604 functions as a timing signal generation circuit indicating the timing for starting scrambling. The M-sequence generator 603 outputs zero until receiving this start signal. Therefore, data sent from the ECC conversion circuit 503 until the counting circuit 604 generates a start signal is sent from the exclusive OR circuit 605 without being scrambled. On the other hand, when the counting circuit 604 generates a start signal, the M-sequence generator 603 generates a randomized signal according to the initial value from the initial value generating circuit 602 in response thereto. This randomized signal is used as a code for scrambling. Therefore, the exclusive OR circuit 605 scrambles and outputs the signal sent from the ECC conversion circuit 503.
[0072]
The configuration of M sequence generator 603 will be described with reference to the block diagram of FIG.
[0073]
The flip-flop circuits FF0 to FF17 included in the M series generator 603 constitute an 18-bit feedback shift register as a whole. That is, the exclusive OR of the outputs of the flip-flop circuits FF0 and FF7 is obtained by the exclusive-OR circuit 701, and this is used as the input of the flip-flop circuit FF17. The address reading circuit 601 reads addresses given as consecutive sector numbers, and sends values from the lower 4 bits to 7 bits (A3 to A6) to the initial value generation circuit 602. The initial value generation circuit 602 generates an initial value according to the received 4-bit value. Since the value A3 of the lower 4th bit changes every 8 sectors, the initial value generation circuit 602 sends an initial value that changes every 8 sectors to the M-sequence generator 603. When a start signal is sent from the counting circuit 604, the initial value from the initial value generating circuit 602 is set in the flip-flop circuits FF0 to FF17 constituting the M-sequence generator 603.
[0074]
The M sequence generator 603 in FIG. 7 is a kind of shift register sequence generator, and is also called a maximum long period sequence generator. A sequence generated by the generator 603 is referred to as a maximum long period sequence or an M sequence. The M sequence generator 603 in FIG. 7 generates an 18th order polynomial expressed by the following equation.
[0075]
H (X) = X ¹⁸ + X ⁷ +1
The M-sequence generator 603 in FIG. 7 has 18 shift registers, so the cycle is n = 2. ¹⁸ -1, i.e. about 32768B. Therefore, the data up to 32768B can be completely randomized by appropriately selecting the initial value.
[0076]
The initial value setting will be described below.
[0077]
The diameter of the record carrier 101 is 120 mm, and a portion of the radius 25 mm to 58 mm is used as an information track area for forming a track. At this time, if the linear density of information recorded on the track is 0.3 μm / bit and the total information capacity per sector including the resync mark, frame address and postamble is 2530B, the length of one sector is about 6 .1mm. This length means that about 26 sectors per circumference are formed on the inner circumference of the record carrier 101 and about 60 sectors per circumference on the outer circumference. As described above with reference to FIG. 7, the initial value generation circuit 602 changes the initial value according to the values of the lower 4 bits to 7 bits (A3 to A6) of the address read by the address reading circuit 601. Therefore, the initial value given to the M-sequence generator 603 changes every time the lower fourth bit value changes, that is, every eight sectors.
[0078]
For example, the value obtained by dividing the period of the M sequence generator 603 into 16 equals the value of the lower 4 bits to 7 bits (A3 to A6) of the address read by the address reading circuit 602, and the M sequence is generated according to the address. When presetting the device 603, even if the same data is recorded, the data is randomized over 128 sectors (= 16 × 8). Since the maximum number of sectors per circumference of the record carrier 101 is about 60 sectors (the value at the outer circumference), if data is randomized over 128 sectors as described above, recording between adjacent tracks is possible. The signal correlation is very low.
[0079]
As described above, the sector address area and subcode area data are not scrambled. In addition, the resync pattern area and the postamble area are not scrambled because they are given after the scramble process. Accordingly, when these regions are adjacent to each other in the radial direction of the adjacent track, the correlation becomes strong. However, the length of the area is 32B even in the total of the sector address area and the subcode area having the largest amount of information, and the length is 100 μm or less, so this is not a problem.
[0080]
The reason why the sector address area is not scrambled is that it is necessary to know the initial value when the original information is obtained from the scrambled information when reproducing the recorded information, that is, when descrambling. . On the other hand, what is recorded in the subcode area is type information indicating whether the recorded information is audio information or image information, and the information is read in a short time without descrambling. Not scrambled for. However, the subcode area may be scrambled. In this case, no problem occurs except that it takes some time to read the subcode area.
[0081]
Next, reproduction of information recorded on the record carrier 101 will be described with reference to FIG.
[0082]
FIG. 8 is a block diagram of a part of the optical information reproducing apparatus 800 according to the first embodiment of the present invention. The optical information reproducing apparatus 800 includes a demodulation circuit 801, a descrambling circuit 802, and an error correction circuit 803.
[0083]
The demodulating circuit 801 demodulates the reproduction signal reproduced from the record carrier using the optical head, and sends the demodulated signal to the descrambling circuit 802. The descrambling circuit 802 reads the address from the received demodulated signal, descrambles the remaining data excluding the 32B data in the sector address area and the subcode area, and sends it to the error correction circuit 803. If an error is included in the information sent from the descrambling circuit 802, the error correction circuit 803 corrects the error and sends the corrected read data.
[0084]
The configuration of the descrambling circuit 802 will be described with reference to the block diagram of FIG.
[0085]
The descrambling circuit 802 basically has the same configuration as that of the scramble circuit 504 of FIG. 6, and includes an address reading circuit 901, an initial value generation circuit 902, an M series generator 903, a counting circuit 904, and an exclusive OR circuit. 905.
The address reading circuit 901 reads a sector address number used as identification information in descrambling from the demodulated signal sent from the demodulating circuit 801, and sends the address number to the initial value generating circuit 902. The initial value generation circuit 902 generates an initial value corresponding to the received address number and sends the initial value to the M sequence generator 903.
[0086]
The counting circuit 904 measures the amount of data sent from the demodulating circuit 801, and generates a descrambling operation start signal when transmission of 32B of information from the head of the sector is completed. Send to M-sequence generator 903. That is, the counting circuit 904 functions as a timing signal generation circuit that indicates the timing for starting descrambling. The M-sequence generator 903 outputs zero until receiving this start signal. Therefore, the data sent from the demodulation circuit 801 until the counting circuit 904 generates the start signal is sent from the exclusive OR circuit 905 without being descrambled. On the other hand, when the counting circuit 904 generates a start signal, the M-sequence generator 903 generates a randomized signal according to the initial value from the initial value generating circuit 902 in response thereto. This randomized signal is used as a code for descrambling. Therefore, the exclusive OR circuit 905 descrambles the signal sent from the demodulation circuit 801 and outputs it.
[0087]
The configuration of the M-sequence generator 903 is shown in FIG. 10, but is the same as the M-sequence generator 603 shown in FIG.
[0088]
That is, the flip-flop circuits FF0 to FF17 included in the M-sequence generator 903 constitute an 18-bit feedback shift register as a whole. That is, the exclusive OR of the outputs of the flip-flop circuits FF0 and FF7 is obtained by the exclusive-OR circuit 701, and this is used as the input of the flip-flop circuit FF17. The address reading circuit 901 reads addresses given as consecutive sector numbers and sends values from the lower 4 bits to 7 bits (A3 to A6) to the initial value generation circuit 602. The initial value generation circuit 902 generates an initial value according to the received 4-bit value. Since the value A3 of the lower 4th bit changes every 8 sectors, the initial value generation circuit 902 sends an initial value that changes every 8 sectors to the M-sequence generator 903. When a start signal is sent from the counting circuit 904, the initial value from the initial value generating circuit 902 is set in the flip-flop circuits FF 0 to FF 17 constituting the M-sequence generator 903.
[0089]
(Second Embodiment)
Hereinafter, a second embodiment of the present invention will be described with reference to FIGS.
[0090]
In the scramble process according to the first embodiment of the present invention described above, when information is read from the record carrier 101, an address can be read if demodulation is performed, and therefore high-speed search can be performed. However, if the address cannot be read, the initial value cannot be determined, and therefore the original data cannot be obtained by descrambling. Therefore, high read reliability of the address is required. However, in general, it is difficult for the record carrier 101 to always read all addresses due to a dropout or the adhesion of dust or dust.
[0091]
In the second embodiment of the present invention, a scramble system will be described in which address reading can be performed accurately and descrambling can be ensured even if dropout, dust, dust or the like adheres.
[0092]
FIG. 11 is a block diagram of a formatter device 1100 that creates record data to be recorded on the record carrier 101 in accordance with the second embodiment of the present invention. In addition, the same number is given to the same component as 1st Embodiment shown in FIG. 5, and the detailed description is abbreviate | omitted.
[0093]
User data is sent to the address assignment circuit 502 from a user data sending device 501 such as a magnetic disk. The address assigning circuit 502 divides the received user data for each 2048B, assigns the sector address and subcode information 32B to the head of each, and sends it to the scramble circuit 1101. The scramble circuit 1101 performs scramble processing on the data and randomizes the data. The scramble circuit 1101 scrambles the data excluding the sector address and 32B corresponding to the subcode, and sends the scrambled data to the ECC conversion circuit 1102. The ECC conversion circuit 1102 arranges the sent data as shown in FIG. 3 and converts it into a code word. Then, the data is sequentially transferred to the modulation circuit 505 from the first column on the left end of the converted codeword pattern. The modulation circuit 505 modulates data by a predetermined modulation method and sends the data to the frame formatter circuit 506. The frame formatter circuit 506 divides incoming data into units of 40B, adds a resync pattern and a frame address to the head, and adds a postamble signal to the end of each to complete the recording data format. To do. The completed recording data is sent to a recording device (not shown).
[0094]
The configuration of the scramble circuit 1101 will be described with reference to the block diagram of FIG.
[0095]
The scramble circuit 1101 includes an address reading circuit 1201, an initial value generation circuit 1202, an M sequence generator 1203, a counting circuit 1204, and an exclusive OR circuit 1205.
[0096]
The address reading circuit 1201 reads the sector address number from the data sent from the address assignment circuit 502 and sends the read address number to the initial value generation circuit 1202. The initial value generation circuit 1202 generates an initial value corresponding to the received address number and sends it to the M-sequence generator 1203. The exclusive OR circuit 1205 sequentially outputs signals according to the exclusive OR of the signal from the address assignment circuit 502 and the signal from the M series generator 1203.
[0097]
The counting circuit 1204 measures the amount of data sent from the address assigning circuit 502, and generates a scramble operation start signal when transmission of 32B of information from the head of the sector is completed. Send to M-sequence generator 1203. The M-sequence generator 1203 outputs zero until receiving this start signal. Therefore, data sent from the address assignment circuit 502 until the counting circuit 1204 generates a start signal is sent from the exclusive OR circuit 1205 as it is without being scrambled. On the other hand, when the counting circuit 1204 generates a start signal, the M-sequence generator 1203 generates a randomized signal according to the initial value from the initial value generating circuit 1202 in response. Therefore, the exclusive OR circuit 1205 scrambles and outputs the signal sent from the address assignment circuit 502.
[0098]
When reading information from the record carrier, the address is read after demodulation and error correction, and descrambling is performed based on the read address to obtain the original information. This will be described with reference to FIG.
[0099]
FIG. 13 is a block diagram of a part of an optical information reproducing apparatus 1300 according to the second embodiment of the present invention.
[0100]
The optical information reproducing apparatus 1300 includes a demodulation circuit 1301, a descrambling circuit 1302, and an error correction circuit 1303.
[0101]
The demodulating circuit 1301 demodulates the reproduction signal reproduced from the record carrier using the optical head, and sends the demodulated signal to the error correction circuit 1302. The error correction circuit 1302 performs error correction on the received demodulated signal and sends the corrected data to the descrambling circuit 1303. The descrambling circuit 1303 reads the address from the received error-corrected data, descrambles the remaining data excluding the 32B data in the sector address area and the subcode area, and sends the read data.
[0102]
The configuration of the descrambling circuit 1303 will be described with reference to the block diagram of FIG.
[0103]
The descrambling circuit 1303 basically has the same configuration as the scramble circuit 1101 of FIG. 12, and includes an address reading circuit 1401, an initial value generation circuit 1402, an M series generator 1403, a counting circuit 1404, and an exclusive OR circuit. 1405.
[0104]
The address reading circuit 1401 reads the sector address number from the signal sent from the error correction circuit 1302 and sends the address number to the initial value generation circuit 1402. The initial value generation circuit 1402 generates an initial value corresponding to the received address number and sends the initial value to the M-sequence generator 1403.
[0105]
The counting circuit 1404 measures the amount of data sent from the error correction circuit 1302, and generates a descrambling operation start signal when transmission of 32B of information from the head of the sector is completed. To the M-sequence generator 1403. The M-sequence generator 1403 outputs zero until receiving this start signal. Therefore, data sent from the error correction circuit 1302 until the counting circuit 1404 generates a start signal is sent from the exclusive OR circuit 1405 without being descrambled. On the other hand, when the counting circuit 1404 generates a start signal, the M-sequence generator 1403 generates a randomized signal according to the initial value from the initial value generating circuit 1402 in response thereto. Therefore, the exclusive OR circuit 1405 descrambles the signal sent from the error correction circuit 1302 and outputs it.
As described above, in the second embodiment of the present invention, the address is read after error correction. For this reason, although the time required for reading the address is slightly increased, even if an error occurs in the information due to dropout or the like, it is corrected correctly. Therefore, the address can be read with extremely high reliability and can be descrambled reliably. However, prior to error correction and descrambling, it is necessary to store all information of one sector in the memory in advance, and for this purpose, a memory having a capacity corresponding to information of one sector is required. On the other hand, in the first embodiment, such a large-capacity memory is not required.
[0106]
When recording information, it is scrambled and then ECC converted. Therefore, the parity area 50 shown in FIG. 3 is not scrambled. However, since the parity area 50 is created for data that has already been scrambled and randomized, the parity area 50 is also randomized as a result. Therefore, the period of the M sequence can be shortened, and the M sequence generator can be simplified.
[0107]
In the first and second embodiments described above, the case of the CLV recording method in which information is recorded by rotating the record carrier at a constant peripheral speed has been described. However, the present invention is not limited thereto.
[0108]
For example, a CAV (Constant Angular Velocity) recording method in which information is recorded by rotating the record carrier at an equiangular speed, or the information linear density of the innermost track of each zone is substantially divided by dividing the record carrier into a plurality of zones. In the case of a ZCAV (Zoned CAV) recording method in which recording is performed in a constant manner, generally, an address number is included in each track and a track number that sequentially assigns a number in the radial direction with one round of the record carrier as one track. Sector numbers for sequentially assigning numbers to each sector in the circumferential direction. In this case, since the sectors are arranged side by side in the radial direction, adjacent tracks have the same sector number. Therefore, an initial value is determined based on the track number, and a randomized signal is generated and scrambled based on the initial value. Thereby, the correlation of signals between adjacent tracks can be reduced. Alternatively, the initial value may be determined based on the least significant digit bit of the track number and the sector number and scrambled.
[0109]
The information capacity of one sector is not limited to 2400B described above. The information capacity of one frame is not limited to 40B described above. The frame address can be omitted.
[0110]
Further, the M-sequence generator is not limited to the one constituted by the 18-stage shift register described above. If the number of stages of the M-sequence generator is increased from 18 stages, the period becomes longer, and if the number is less than 18, the period is shortened. The number of these stages can be arbitrarily selected depending on the format or information density.
[0111]
Further, the change of the initial value of the M-sequence generator is not limited to the above-described 8 sectors. For example, the configuration may be changed every 1 sector or every 16 sectors. Specifically, the initial value may be changed in units of a number smaller than the number of sectors per circumference of the innermost track. By changing the initial value in this way, even when the same data is continuously recorded, the correlation of recording information between adjacent tracks is reduced. However, the initial value of the M-sequence generator is 2 ⁿ If it is changed for each sector (n is a positive integer), the configuration of the initial value generating circuit becomes simpler.
[0112]
Furthermore, the circuit that can be used in the scramble circuit or the descramble circuit is not limited to the above-described M-sequence generator. Other configurations may be used as long as the randomized signal is generated according to a predetermined rule with respect to the initial value.
[0113]
The error correction code may be a product code or CIRC (Cross Interleaved Reed-Solomon code) used in a compact disc. Further, the signal for determining the initial value may be identification information that can identify the position, and may be, for example, a time code indicating time.
[0114]
【The invention's effect】
As described above, in the optical information recording carrier, the optical information recording method, the optical information recording apparatus, and the optical information reproducing apparatus of the present invention, a spiral or concentric circle is formed on the surface of the disk-shaped substrate. Information scrambled based on an initial value corresponding to the value of identification information for identifying the sector position is recorded in at least a plurality of sectors included in the track. As a result, the data scrambled and randomized is recorded on the record carrier. Since different data is recorded between adjacent tracks, signal correlation between them is reduced. For this reason, the influence of the crosstalk is randomized and the influence on the track deviation signal is reduced, and stable tracking control can be performed even if the track pitch is narrowed.
[0115]
As identification information used when information is scrambled, for example, sector numbers assigned to a plurality of sectors can be used. Since the sector number is inevitably necessary for data recording, it can be easily used as identification information. Further, there is no need to provide a circuit for generating identification information.
[0116]
If the initial value at the time of scramble is changed for each predetermined number of sectors in the circumferential direction, even if data of the same content is continuously recorded, the scrambled and randomized data is stored on the record carrier. To be recorded.
[0117]
The initial value is 2 ⁿ If it is changed for each sector (n is a positive integer), the configuration of the initial value generating circuit can be simplified.
[0118]
If the initial value is changed for each number of sectors smaller than the number of sectors per track of the innermost track, even if information of the same content is continuously recorded in the innermost track, The recorded data is reliably randomized.
[0119]
When recording scrambled information, the information is first divided into a plurality of sectors, each of the divided information is scrambled based on an initial value corresponding to the value of the identification information, and then scrambled with the identification information. The information may be converted into a codeword that can be error-corrected. In this case, information converted into a code word is recorded in each of a plurality of sectors. As a result, since the address is read after error correction is performed, the time required for reading the address is slightly increased. However, even if an error occurs in the information due to dropout or the like, it is corrected correctly. Therefore, the address can be read with extremely high reliability and can be descrambled reliably.
[0120]
Alternatively, when recording the scrambled information, the information was divided into a plurality of sectors, and then the identification information and the divided information were converted into error-correctable codewords prior to the scramble process. A portion of the code word excluding the identification information may be scrambled based on an initial value corresponding to the value of each identification information. As a result, when reading information from the optical information record carrier, the address can be read by simply performing demodulation, so that a high-speed search can be performed, and a large-capacity memory is not required to read the address.
[Brief description of the drawings]
FIG. 1 is a schematic plan view of an optical information record carrier.
FIG. 2 is a diagram showing a format of information recorded on an optical information record carrier, where (a) is a format of one track, (b) is a format of one sector, and (c) is a first format, respectively. The format of the information area of the frame, (d) shows the format of the sector address.
FIG. 3 is a diagram schematically showing an outline of an arrangement pattern of information of a total of 2400B recorded in one sector as an error correction code after a parity area is added.
FIG. 4 is a diagram schematically showing a format of recording data recorded on an optical information record carrier.
FIG. 5 is a block diagram of a formatter device for creating record data to be recorded on a record carrier according to the first embodiment of the present invention.
6 is a block diagram of the scramble circuit shown in FIG. 5. FIG.
7 is a block diagram of an M-sequence generator included in the scramble circuit shown in FIG.
FIG. 8 is a block diagram of a playback apparatus for playing back data recorded on a record carrier according to the first embodiment of the present invention.
9 is a block diagram of the descrambling circuit shown in FIG. 8. FIG.
10 is a block diagram of an M-sequence generator included in the descrambling circuit shown in FIG.
FIG. 11 is a block diagram of a formatter device for creating record data to be recorded on a record carrier according to a second embodiment of the present invention.
12 is a block diagram of the scramble circuit shown in FIG. 11. FIG.
FIG. 13 is a block diagram of a playback apparatus for playing back data recorded on a record carrier according to the second embodiment of the present invention.
14 is a block diagram of the descrambling circuit shown in FIG.
[Explanation of symbols]
10 Sector address area
20 Subcode area
30 data areas
40 Original data area
50 Parity area
60 Codeword area
101 record carrier
102 tracks
500, 1100 formatter device
501 User data sending device
502 Address assignment circuit
503, 1102 ECC conversion circuit
504, 1101 scramble circuit
505 modulation circuit
506 Frame formatter circuit
601, 901, 1201, 1401 Address reading circuit
602, 902, 1202, 1402 Initial value generation circuit
603, 903, 1203, 1403 M-sequence generator
604, 904, 1204, 1404 counting circuit
605, 701, 905, 1205, 1405 exclusive OR circuit
800, 1300 playback device
801, 1301 demodulation circuit
802, 1303 Descramble circuit
803, 1302 error correction circuit

Claims (5)

Identification information for identifying the position is given for each unit of a predetermined amount of data, and the data identified by the identification information is scrambled and spiral-shaped based on an initial value corresponding to the value of the identification information. Or a disc-shaped record carrier formed concentrically,
The record carrier, wherein the initial value is changed within the circumference of the innermost circumference of the record carrier, and the data is scrambled with a maximum long-period sequence based on the initial value. Discrimination is performed by giving identification information for identifying the position for each unit of a predetermined amount of data and scrambling the data identified by the identification information based on an initial value corresponding to the value of the identification information. An information recording method for recording on a record carrier in a spiral or concentric manner,
Generating an initial value whose value changes within the circumference of the innermost circumference of the record carrier in accordance with the identification information;
Generating a maximum long period sequence based on the initial value;
A scrambling step of scrambling the data identified by the identification information in the maximum long period sequence;
Converting the identification information and the scrambled data into an error-correctable codeword;
Recording information on the record carrier based on the error correctable codeword;
A method of recording information. Discrimination is performed by giving identification information for identifying the position for each unit of a predetermined amount of data and scrambling the data identified by the identification information based on an initial value corresponding to the value of the identification information. An information recording device for recording spirally or concentrically on a record carrier,
In accordance with the identification information, an initial value generating means for generating an initial value whose value changes within the circumference of the innermost circumference of the record carrier;
Maximum long period sequence generating means for generating a maximum long period sequence based on an initial value from the initial value generating means;
Scrambling means for scrambling the data identified by the identification information in a maximum long period sequence from the maximum long period sequence generating means;
Error correction code generation means for converting the identification information and the scrambled data into an error-correctable codeword;
Recording means for recording information on the record carrier based on codewords from the error correction code generating means;
An information recording apparatus comprising: Identification information for identifying the position is given for each unit of a predetermined amount of data, and the data identified by the identification information is scrambled and spiral-shaped based on an initial value corresponding to the value of the identification information. Or an information reproducing method for reproducing information from a disc-shaped record carrier formed concentrically,
The data is scrambled in a maximum long-period sequence based on an initial value that changes within the circumference of the innermost circumference of the record carrier in accordance with the identification information for identifying the position of the data. The identification information and the scrambled data are recorded in a format converted into an error-correctable codeword,
The method
Demodulating a reproduced signal reproduced from the record carrier to generate a demodulated signal;
Correcting the error contained in the demodulated signal to generate corrected information;
Generating an initial value based on the identification information included in the corrected information;
Generating a maximum long period sequence for descrambling based on the initial value;
Descrambling the data with the maximum long period sequence;
A method of reproducing information. Identification information for identifying the position is given for each unit of a predetermined amount of data, and the data identified by the identification information is scrambled and spiral-shaped based on an initial value corresponding to the value of the identification information. Or an information reproducing apparatus for reproducing information from a disc-shaped record carrier formed concentrically,
The data is scrambled in a maximum long-period sequence based on an initial value that changes within the circumference of the innermost circumference of the record carrier in accordance with the identification information for identifying the position of the data. The identification information and the scrambled data are recorded in a format converted into an error-correctable codeword,
The device
Demodulation means for demodulating a reproduction signal reproduced from the record carrier to generate a demodulation signal;
Error correction means for correcting the error contained in the demodulated signal to generate corrected information;
An initial value generating means for generating an initial value based on the identification information included in the corrected information;
Maximum long period sequence generating means for generating a maximum long period sequence for descrambling based on the initial value;
Descrambling means for descrambling the data in the maximum long-period sequence;
An information reproducing apparatus comprising:

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