JPH11265549A - Information signal recording medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain the stabilizing of a tracing control by setting a cycle in which scrambling signals make a round to a length equal to or longer than that of the quantity of information to be included in an information track having the largest storage capacity to eliminate the correlativity between adjacent tracks. SOLUTION: A scrambling means 1 generates an initial value from an initial value storage part 2 based on a sector address signal S1 from a sector address part and generates scrambling signals S2 of M series from an M series generating part 3 based on the initial value and forms a recording signal S4 by performing a scrambling operation while adding the scrambling signals S2 to information signal S3 in an adder 4. At this time, a cycle in which the scrambling signals make a round is set to a length equal to or longer than that of the quantity of information of an outermost peripheral track. Thus, the correlativity between adjacent tracks can be completely eliminated and it is made possible to perform a stable tracking control even when a track pitch is narrowed in order to increase the density of a recording medium.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an information recording medium in which an information signal scrambled by a scramble signal is recorded on a circular information track.

[0002]

2. Description of the Related Art Generally, in an optical disk such as a compact disk (CD), a digital signal is recorded on a track of the disk by forming irregularities called pits and lands, and reflected light from the pits and lands is optically reflected. The light is received by a 4-split photodetector in the head, converted into an electric signal, and the signal is read.

[0003] Focusing is for causing the objective lens of the optical system of the pickup to follow the surface deflection of the disk, and there is an astigmatism method as a method. The tracking is for causing the pickup to follow the track with respect to the eccentricity of the disk. Examples of the method include a three-beam method, a push-pull method, and a heterodyne method. Focusing and tracking are 2
The operation is performed by calculating the output signals of the divided sensors of the divided or four-divided photodetectors to obtain a focusing control signal and a tracking control signal, and then performing servo control.

The laser beam emitted from the pickup has a phase difference between the reflected light from the pit portion and the reflected light from the land portion, and due to the interference effect, the amount of reflected light incident on the photodetector at the pit portion and the land portion is reduced. Due to the difference, a reproduced signal is obtained. In the recorded data, in a CD, a signal subjected to digital modulation called EFM is recorded in a pattern of pits and lands.
The recorded data is binarized from a reproduction signal due to a change in the amount of light at the pits and lands, and digitally demodulated to reproduce the data.

[0005]

The signal recording system includes a constant angular velocity system CA in which the angular velocity of the disk is constant.
V (Constant Anglar Velocit)
y) and a constant linear velocity CLV (Cons
Tant Linear Velocity) is known, and the CAV method has a structure in which the number of sectors included in each track is equal, and the head of each sector completely coincides with the radiation from the center of the disk for all tracks.

In the CLV system, since the linear velocity is constant,
Although the heads of the sectors in all the tracks do not match, the heads of the sectors may coincide with the radiation from the center of the disk for some adjacent tracks. In such a situation, in the case where information of the same content, for example, image information or music information is recorded, when recording a large amount of silence between songs, silent sections between chapters, non-image sections, etc. Generally, a scramble operation is performed in order to prevent recording signals having the same shape and arrangement from appearing.

[0007] This scrambling is to prevent a synchronizing signal for synchronizing the head of the information sector from being generated as a pseudo synchronizing signal in the data, and to provide a DS of EFM modulation.
This is performed for the purpose of improving V controllability, and a scramble signal is generated by an exclusive OR of the information signal and the M sequence. The M-sequence used for scrambling is a cyclic code represented by 2x-1 0s or 1s. For example, a known scrambling means employed in a CD-ROM uses an M-sequence of 215-1 = 32767 cycles, and is performed using the same initial value for each sector.

Here, a conventional information signal recording method will be described with reference to FIGS. 6A and 6B. The sector address signal S1 is generated by the M-sequence generator 1 of the scrambler 10.
1 generates a scramble signal S10. The scramble signal S10 generates an information signal S3.
Are scrambled by the adder 12, and a recording signal S4 to be actually recorded on the recording medium is output. The M-sequence at this time is a cyclic code represented by 2x-1 0s or 1s (see FIG. 6B).

In the current trend of optical discs, the recording capacity has been increased. However, the information having the same content as described above is recorded on the radiation from the center of the disc by using the conventional scrambling means. When recorded at a position where the heads match, the shapes of the pits and lands between adjacent tracks match, so that the correlation increases, the amplitude of the tracking error signal decreases, and the signal-to-noise ratio (S / N) increases. And tracking control is not performed stably.

[0010] The present invention focuses on the above problems,
The purpose of this information signal is to effectively solve this problem, and the purpose is to increase the period of the scrambled signal or to partially use the scrambled signal to remove the correlation between adjacent tracks. It is to provide a recording medium.

[0011]

SUMMARY OF THE INVENTION According to the present invention, there is a problem that a scrambling process is performed using a short-period M-sequence scramble signal despite that a plurality of sectors are included in one track. It is made by obtaining the knowledge that the problem is caused by the above.

According to a first aspect of the present invention, in order to solve the above-mentioned problems, a scramble signal is used when an information signal composed of a binary digital signal sequence is recorded on an information recording medium having a circular information track. In the information signal recording medium scrambled by the above, the cycle in which the scramble signal makes a round is set to a length equal to or longer than the information amount included in the information track having the largest recording capacity.

According to a second aspect of the present invention, in order to solve the above-mentioned problem, a scramble signal is used when an information signal composed of a binary digital signal sequence is recorded on an information recording medium having a circular information track. In the information signal recording medium scrambled by the above, a part of the scramble signal is used in an overlapping manner.

According to the first aspect, before the recording of the information signal on the information recording medium, the recording signal is generated by the scrambling means so that the information having the same content does not appear on the adjacent track. This scrambling means generates a scrambling signal having a cyclic period set to a length equal to or longer than the information amount of a track including the largest number of sectors among the information tracks on the disk. As a result of applying the scramble signal, the stability of the tracking control can be ensured, so that the distance between adjacent tracks can be reduced, and a disk with a high recording density can be realized.

According to the second aspect of the present invention, a part of the scramble signal is used at the time of recording the information signal. This makes it possible to shorten the period of the scramble signal as compared with the case of the first aspect, and to ensure the stability of tracking control.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of an information signal recording medium according to the present invention will be described below in detail with reference to the accompanying drawings. FIG. 1 is a block diagram showing a scrambling means of a recording signal generator for implementing the present invention.

As shown in FIG. 1A, this scrambling means 1 generates an initial value stored in advance based on an address signal S1.
And an M-sequence generating unit 3 for generating an M-sequence scramble signal S2 based on the output from the storage unit 2, and a scrambling operation by adding the scramble signal S2 to the information signal S3 comprising a digital signal sequence. And the adder 4 forming the recording signal S4. At this time, as shown in FIG. 1B, a predetermined length Dw from the initial value of one M sequence to the initial value of the next M sequence is obtained.
Has been shifted only. The initial value storage unit 2 reads the initial value based on the address value of the address signal S1.

FIG. 2 shows the scrambling procedure and M according to the present invention.
FIG. 3 is a diagram showing the relationship between streams, as shown in FIG. 2A, for example, a Tn-th track and a T (n + 1) -th track are recorded concentrically or spirally in a recording area of an information recording medium 5 such as a disk. Is done. In the illustrated example, the recording method of the CLV system is shown, and the sector of each track starts from the radiation L from the center point O of the disk. FIG.
FIG. 2B is a diagram in which information recorded on the adjacent track at this time is rewritten linearly, and FIG. 2C shows the arrangement of recording signals at this time.

Here, in describing the method of determining the order and initial value of the M-sequence used in the scrambling means of the present invention, the recording method will be described by taking the CLV method as an example, and constants relating to the disk to be recorded are given as follows. Keep it. Smin: number of sectors included in the innermost circumference Smax: number of sectors included in the outermost circumference Dw: shift width (unit: sector) from the initial value of one M series to the initial value of the next M series (0 <Dw) , However,
This Dw is variable. Cycle: the maximum number of sectors that can be represented by the cyclic period (2x-1) of the M sequence Bsect: the number of bytes of information contained in one sector

<Embodiment 1> FIG. 3 shows a first embodiment of the present invention.
1 shows an embodiment of the content of the invention, and shows a positional relationship between information recorded on the outermost track and a track adjacent to the outermost track through a scrambling procedure. FIG.
The (A) M-sequence diagram in which the cyclic period of the scrambled signal is longer than the amount of information recorded on the outermost periphery corresponds to the information recorded on the outermost periphery in a 1: 1 relationship. Is shown.

The arrangement of the recording signal shown in FIG.
As shown in FIG. 2, in actuality, the recording signal is arranged concentrically or spirally from the center point O of the disk, and the information recorded on the adjacent track starting from the radiation L from the center point O of the disk in FIG. It is the figure which was rewritten in the shape of a straight line. Due to the nature of the M-sequence, even if a large amount of the same information is recorded, different recording signals are generated in the range of the amount of information recorded on the outermost periphery. , Different signals are recorded on the radiation L from the center point O of the disk of the adjacent track.

From the above, the condition of the order of the M-sequence to be used is as shown in Equation 1. Smax ≦ Cycle (1) Here, when the cycle is expressed in sector units, it is as shown in Expression 2. Cycle = (2 × −1) / (8 · Bsect) (2) Accordingly, the order x of the M sequence to be obtained can be obtained by Expressions 3, 4, and 5. it can.

Smax ≦ (2x−1) / (8 · Bsect) (3) 2x ≧ 8 · Bsect · Smax + 1 (4) x ≧ log2 (8 · Bsect · Smax + 1) (5) Therefore, the information signal S3 is calculated by M defined by the order obtained by the above equation (5). By performing the scrambling operation with the scramble signal S2 of the cyclic cycle (2x-1) of the sequence, it is possible to obtain the recording signal S4 capable of performing stable tracking.

For example, in a CD-ROM, the amount of information contained in one sector is 2352 bytes, and the number of sectors contained in the outermost periphery is about 22 sectors. By using the following M-sequence,
In all tracks from the innermost circumference to the outermost circumference, different signals are recorded on the radiation from the center point of the disk of the adjacent track. As described above, the cycle in which the scramble signal S2 makes one round is set to a length larger than the information amount of the track having the largest recording capacity, that is, the outermost track, so that the correlation between adjacent tracks can be completely eliminated. it can. Therefore, stable tracking control can be performed even if the track pitch is narrowed to increase the density of the recording medium.

<Embodiment 2> Next, a second invention method will be described. FIG. 4 shows an embodiment of the second invention as defined in claim 2, showing the positional relationship between information recorded on the innermost track and a track adjacent to the innermost track via a scrambling procedure. I have.

In the M-sequence diagram in FIG. 4A, in this case, it is assumed that the cyclic period of the scrambled signal is a cyclic period larger than the number of information bits included in at least two sectors. As shown in the M-sequence diagram in FIG. 4A, a scramble operation is performed for each sector using an initial value shifted by a shift width Dw from the initial value used in the previous sector. The arrangement of the recording signals shown in FIG. 4B actually corresponds to the center point O of the disk as shown in FIG.
FIG. 3 is a diagram in which information concentrically or spirally arranged is rewritten linearly with information recorded on an adjacent track starting from a radiation L from a center point O of the disk in FIG.

The problem here is that the sector 1 which is the signal of the first sector recorded on the innermost track and the sector located at the same position as the sector 1 on the adjacent (innermost track + 1) track Signal (sector (n + 1), sector (n +
2)). In FIG. 4B, when a scramble signal including the scramble signal used in the sector is used as a problematic part, if the information to be recorded is the same, the signal including the signal equal to the sector 1 is recorded. Will do.

Therefore, in the case of a disk on which information for a sector corresponding to Smin can be recorded on the innermost circumference, one sector starts from the M-sequence portion used in sector 1 when the scrambling procedure of sector (Smin + 1) is performed. M used for
The scrambling operation may be performed using the initial value of the M sequence shifted by the sequence code or more. The above contents are expressed as shown in Expression 6 when expressed by an expression. Smin · Dw ≧ 1 (6)

Next, consider the outermost track of the disk. Originally, the outermost track and (the outermost track-1) are considered, but here, it is assumed that (the outermost track + 1) track exists. The idea of not generating the same scramble pattern in adjacent tracks is exactly the same, and here, how to give a constant is shown.

When the order of the M-sequence is determined by the information bits included in the outermost periphery, the scramble pattern used in the outermost periphery is recorded exactly at (the outermost periphery + 1). The number of sectors included, plus the number of sectors (1 / Dw) until a part of the first used M sequence on the outermost circumference is no longer used, may be selected as an M sequence having a cycle equal to or longer than one cycle. become.
Therefore, it suffices to satisfy the condition shown in Expression 7. (Smax + 1 / Dw) · Dw ≦ Cycle (7)

From the above equations 6 and 7, the following equation 8 can be obtained. 1 / Smin.ltoreq.Dw.ltoreq. (Cycle-1) / Smax (8) Here, Smin and Smax can be determined depending on the disc to be recorded. Therefore, when the cycle shown in the equation is re-expressed in sector units, it becomes as shown in equation 9. Cycle = (2x -1) / (8 · Bsect) ・ ・ ・ ・ (9)

Therefore, from the left and right sides of the above equation 8, M
The order x of the sequence can be obtained by the following Expressions 10, 11, and 12. 1 / Smin ≦ [(2 × −1) / (8 · Bsect) −1] / Smax (10) 2x ≧ 8 · Bsect (1 + Smax / Smin) +1 (11) x ≧ log2 [ 8 · Bsect · (1 + Smax / Smin) +1] · (12) Thus, the order x of the M sequence can be determined.
The left side and the right side of Equation 7 are both constants, and the deviation width Dw
Can also be determined.

For example, in a CD-ROM, the amount of information included in one sector is 2352 bytes, and the number of sectors included in the outermost and innermost circumferences is about 22 sectors and 9 sectors, respectively. To calculate the order x
It turns out that M-sequences of order 16 or higher should be used. As a result, in all the tracks from the innermost circumference to the outermost circumference,
Different signals are recorded on the radiation L from the center point O of the disk of the adjacent track. Also, when compared with the result of the first embodiment, the function of removing the correlation between adjacent tracks requires a 19-order M-sequence if the method of the first invention shown in the first embodiment is used.
If the method of the second invention described in the second embodiment is used, a similar effect can be obtained using a 16-order M-sequence.

As described above, the correlation between the adjacent tracks can be completely eliminated by using a part of the scramble signal in an overlapping manner as in the first invention, and even when the track pitch is narrowed, the correlation is stable. Tracking control can be performed.

<Embodiment 3> Next, a modification of the second invention will be described. FIG. 5 is a diagram showing the positional relationship of information recorded on the innermost track and the outermost track when a scramble procedure different from that of the above embodiment is performed.
In the M-sequence diagram shown in FIG. 5A, in this case, it is assumed that the cyclic period of the scrambled signal is a cyclic period that is larger than the number of information bits included in at least two sectors, and one scramble pattern is used. An initial value is provided so that the same pattern is included in the next scramble pattern only in the range of 1-Dw. FIG. 5 (B) and FIG.
The arrangement of the recording signal shown in (C) is a concentric or spiral arrangement from the center O of the disk, as shown in FIG. 2, and the radiation from the center O of the disk in FIG. FIG. 14 is a diagram in which information recorded on an adjacent track is rewritten linearly starting from L.

First, consider the innermost track of the disk. As a concept, as in the second embodiment, the problem is that the radiation L from the center point O of the disk in the area where the sector 1 is recorded, which is the signal of the first sector recorded on the innermost circumference, and the track adjacent thereto are recorded. This is a location related to the inside of the first and last areas of the sector 1. In FIG. 5B, after the sector (n + 1), the scrambling procedure can be performed using the initial value of the scramble signal having a distance deviated by the amount of information included in one sector from the initial value of the scramble signal used in the sector 1. It is good. Here, the number of times one scramble signal is used repeatedly and continuously is Mlo
If it is op, it is expressed as shown in Expression 13. (Smin / Mloop) · Dw ≧ 1 (13)

Next, consider the outermost track of the disk. Originally, the outermost track and (the outermost track-1) are considered, but here, it is assumed that (the outermost track + 1) track exists. The idea of not generating the same scramble pattern in adjacent tracks is exactly the same, and here, how to give a constant is shown.

If the order of the M-sequence is determined by the information bits included in the outermost periphery, the (outermost periphery + 1) is recorded exactly the same as the scramble signal used in the outermost periphery. +1) The scrambled signal used for the sector located on the same radiation as the first outermost track in the track may use a scrambled signal that is Bsect or more before the scrambled signal used first in the outermost track. 14 are provided. [(Smax / Mloop) + 1 / Dw] · Dw ≦ Cycle (14)

From Expressions 13 and 14, the following Expression 15 can be obtained. Mloop / Smin ≦ Dw ≦ (Cycle-1) · Mloop / Smax (15) Here, Smin and Smax can be determined depending on the disk to be recorded. Therefore, the cycle shown in the equation can be expressed in the unit of sector as shown in the following equation 16. Cycle = (2x-1) / (8 · Bsect) (16)

From the left and right sides of the above equation (15), the order x of the M series can be obtained by the following equations (17), (18) and (19). Mloop / Smin ≤ [(2x-1) / (8 Bsect) -1] Mloop / Smax (17) 2x ≧ 8 Bsect (1 + Smax / Smin) +1 (18) x ≧ log2 [8 Bsect (1 + Smax / Smin) +1] (19) Equation 12 is exactly the same, and it can be seen that the same result is obtained.

Therefore, when compared with the result of the first invention method of the first embodiment, the function of removing the correlation between adjacent tracks requires a 19-order M-sequence if the method of the first embodiment is used. When the method of the third embodiment is used, similar effects can be obtained by using a 16-order M-sequence, as in the result of the second embodiment. Further, by repeatedly using one scramble signal, an effect is obtained that the number of initial values recorded in the initial value storage unit 2 in FIG. 1 is made smaller than in the case of the second embodiment. In the above-described embodiment, the case of recording by the CLV method has been described.
Needless to say, the present invention can be applied to the case where recording is performed by the AV system.

[0042]

As described above, according to the information signal recording medium of the present invention, the following excellent operational effects can be exhibited. According to the first aspect, the cycle in which the scramble signal loops is set to a length equal to or longer than the information amount included in the outermost information track having the largest recording capacity.
Correlation between adjacent tracks can be completely removed. Therefore, stable tracking control can be performed even if the track pitch is narrowed to increase the density of the information recording medium. According to the second invention, the correlation between adjacent tracks can be completely removed by using a part of the scramble signal in an overlapping manner. , A stable tracking control can be performed. Also, the order of the M-sequence can be reduced as compared with the first invention,
The scrambling means can be simplified accordingly.

[Brief description of the drawings]

FIG. 1 is a block diagram showing scrambling means for implementing the present invention.

FIG. 2 is a diagram showing a relationship between M sequences in a scrambling procedure of the present invention.

FIG. 3 is a diagram linearly showing a scramble pattern on the outermost circumference and the next outer circumference in the first invention.

FIG. 4 is a diagram linearly showing a scramble pattern on the innermost circumference and the next inner circumference in the second invention.

FIG. 5 is a diagram linearly showing a scramble pattern in a track adjacent to each of an innermost circumference and an outermost circumference in a modification of the second invention.

FIG. 6 is a block diagram showing a conventional scrambling means.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Scramble means, 2 ... Initial value storage part, 3 ... M sequence generation part, 4 ... Addition part, 5 ... Information recording medium, L ... Radiation,
O: center point, S1: sector address signal, S2: scramble signal, S3: information signal, S4: recording signal.

Claims (4)

[Claims] 1. An information signal recording medium having a circular information track in which an information signal composed of a binary digital signal sequence is scrambled and recorded by a scramble signal obtained from a cyclic code, wherein the scramble signal is a single round. The period of the information track is set to be equal to or longer than the amount of information contained in the outermost information track, and the correlation between the adjacent information tracks on the radiation from the center point of the information recording medium is removed. Information signal recording medium. 2. An information signal having a circular information track in which an information signal comprising a binary digital signal sequence divided into a plurality of sectors is scrambled for each sector by a scramble signal obtained from a cyclic code and recorded. In the recording medium, since each of the scrambled signals scrambled in each of the sectors is partially used in an overlapping manner, an information amount included in an outermost information track includes a cycle in which the scrambled signal makes a round. An information signal recording medium, wherein a correlation between adjacent tracks on a radiation from a center point of the information recording medium is removed by setting the length to the following length. 3. A circular information track in which an information signal consisting of a binary digital signal sequence divided into a plurality of sectors having address values is scrambled and recorded for each sector by a scramble signal obtained from a cyclic code. An information signal recording medium having: a value obtained based on the address value as an initial value, by using the scramble signal generated from the cyclic code, the radiation from the center point of the information recording medium 2. An information signal recording medium according to claim 1, wherein the correlation between adjacent tracks is removed. 4. The information signal recording medium according to claim 2 or 3, wherein the same scramble signal obtained by setting the same initial value is repeatedly used for the information signal of a plurality of sectors. An information signal recording medium, wherein correlation between adjacent tracks on a radiation from a center point of the information recording medium is removed.