CN100594548C - How to initialize a disc - Google Patents

Abstract

An information reproducing method for reproducing information by means of an optical disc comprising a first track on which information is recorded and/or reproduced, and a second track on which information is recorded and/or reproduced, the first track Formed on the same recording surface as the second recording track, the first recording track is in the shape of a groove, and the second recording track is in the shape of a land sandwiched between the first recording tracks. When initializing the optical disc In the process of: recording the capacity block management identification in the optical disc management area of the first recording track and the second recording track, the capacity block management identification indicates that the recording and reproduction by the first recording track and the second recording track The capacity block structure of the data.

Description

How to initialize a disc

This application is a divisional application of a Chinese patent application with an application date of June 8, 1994, an application number of 03145744.4, and an invention title of "Optical Disc and Information Recording/Reproducing Device".

technical field

The present invention relates to an information reproducing method.

Background technique

An optical disc is a large-capacity high-density memory with which non-contact recording and reproduction can be realized, and one optical disc can be replaced by another optical disc. The capacity of a typical optical disc is as follows: when the optical read-write head uses a lens with an NA (numerical aperture) of 0.5, a 130mm optical disc has a single-sided capacity of 300 to 500MB, while a 90mm optical disc has a single-sided capacity of about 128 to 250MB. In order to adapt to multimedia applications, a high-density recording/reproducing technology has been studied, which uses a short-wavelength laser with a wavelength of 680mm to obtain a capacity about 2 to 4 times the above-mentioned capacity.

Figure 10 shows a plan view (top) and a cross-sectional view (bottom) of a continuous servo track format in a prior art optical disc.

Figure 10(a) shows a continuous servo track employed in a prior art 130mm or 90mm optical disc, which has a land track format. In the land track format, the track includes a groove 2 formed on a transparent substrate 1, and the depth of the groove 2 is λ/(8·n) (λ is the laser wavelength, n is the refraction of the substrate 1 rate, the same below), the pit 4 constitutes a sector identification (ID) signal, and the record character 5 is recorded on the land 3 (clamped in) by the recording track. The pit 4 used as an ID signal is a concave-convex pit having a phase depth of λ/(4·n).

The track pitch is chosen to be approximately λ/NA, ie depending on the laser wavelength (λ) and the lens aperture (NA). In the prior art optical disk, since the land must remain between the groove 2 and the ID signal pit 4, it is difficult to reduce the track pitch to 1.3 μm or less from the viewpoint of the land forming process.

Fig. 10(b) shows an example of the groove recording track format, wherein each recording track is formed by a simple groove 6 and a land 7 with a phase depth of λ/(8Nn), the pit 8 constitutes an ID signal, and a data signal is recorded therein The record character 9 is recorded in the groove 6. Since the track structure of such a groove recording track is constituted by simple grooves 6, an optical disc having a track pitch of 1 µm or less can be produced relatively easily.

Fig. 10(c) shows an example of a land/groove track format in which a groove track is formed by setting the width of a groove 11 having a depth of approximately λ/(8·n) to half the track pitch, Signal 12 is also recorded on land 10 . In principle, this land/groove recording can achieve twice the surface recording density of the land recording shown in Fig. 10(a).

Generally, when the track pitch is reduced, crosstalk about signals recorded in adjacent tracks; cross erasure in which signals recorded in adjacent two tracks are erased together due to data recording, and problems in track servo stability will be produce.

The stability of the track servo will be discussed next. In the land recording track 10 for the land/groove recording shown in FIG. 10(c), the track pitch is half of λ/NA. With λ of 830 mm and NA of 0.5, even when the track pitch for recording signals is 0.8 µm, track servo can be performed with respect to the track pitch of 1.6 µm constituting each groove and land. Therefore, the track servo can work stably regardless of the commonly used three-beam method or the push-pull method.

Even in the land/groove recording using the recording method described above, when the track pitch is further reduced to increase the recording density, there is a problem of crosstalk occurring between the recording track including the groove 11 and the recording track including the land.

Especially in the case of using an optical read-write head with a laser wavelength λ of 830nm and a lens aperture NA of 0.5, when the track pitch is 1.6 μm, a crosstalk of -30 to -35 dB will be generated, and when the track pitch is 0.8 μm, the crosstalk will be A crosstalk of -15 to -20 dB is generated, thereby causing a problem that ID signals and data signals cannot be reproduced normally.

In particular, there is also the following problem: as in the track search process, it is difficult to confirm the target track due to some reproduction errors, for example, the ID signal is erroneously reproduced due to the influence of the crosstalk of the ID signal, or the erroneous reproduction of the adjacent track. ID signal. Also, during recording in an unrecorded sector, even when an ID signal leaks from an adjacent track, reproduction seems to proceed normally, thereby causing data to be recorded on a wrong sector.

However, in the above-mentioned groove/land recording, although the recording track density is doubled, there arises problems during recording or reproduction, and errors due to crosstalk or cross erasure exceed the standard, The number of bad sectors also increases as a result.

Contents of the invention

In view of the problems of the prior art recording methods, an object of the present invention is to provide an information recording/reproducing method in which defect replacement processing can be quickly realized.

The present invention provides an information reproducing method for reproducing information by means of an optical disc comprising a first track on which information is recorded and/or reproduced and a second track on which information is recorded and/or reproduced, said first A recording track and a second recording track are formed on the same recording surface, the first recording track is in the shape of a groove, and the second recording track is in the shape of a land sandwiched between the first recording tracks. In the process of the optical disc: record the capacity block management identification in the optical disc management area of the first recording track and the second recording track, the capacity block management identification indicates that the first recording track and the second recording track A capacity block structure for recording and reproducing data.

Description of drawings

Fig. 1 represents the sector format of an optical disc of the first embodiment of the present invention;

Fig. 2 represents the sector format of an optical disc of the second embodiment of the present invention;

Fig. 3 represents the sector format of an optical disc of the third embodiment of the present invention;

Fig. 4 represents the format of the ID signal of the 4th embodiment of the present invention and the structure of optical disk;

Fig. 5 is a block diagram of an information recording/reproducing device embodiment applied to the optical disc of the present invention;

Fig. 6 is a block diagram of a focus tracking control circuit embodiment in the embodiment shown in Fig. 5;

Fig. 7 is a block diagram of a sector ID reproduction circuit embodiment in the embodiment shown in Fig. 5;

Fig. 8 is a block diagram of another sector ID reproduction circuit embodiment in the embodiment shown in Fig. 5;

Fig. 9 is a block diagram of a sector recording/reproducing control circuit embodiment in the embodiment shown in Fig. 5;

Fig. 10 shows the information recording carried out on the optical disc of prior art;

Fig. 11 is a block diagram showing a part of construction of an embodiment of an information recording/reproducing apparatus applied to the optical disc of the present invention;

FIG. 12 is a block diagram showing the configuration of the remaining parts of an embodiment of an information recording/reproducing apparatus applied to an optical disc of the present invention;

Fig. 13 shows the appearance of an optical disc according to an embodiment of the present invention, wherein the first recording track records information in the groove, and the second recording track records information on the groove land;

Fig. 14 shows the spare area in the optical disc of the first embodiment of the present invention;

Fig. 15 shows the spare area in the optical disc of the second embodiment of the present invention;

Fig. 16 shows the spare area in the optical disc of the third embodiment of the present invention;

Fig. 17 shows the embodiment of the management information stored in disc identification areas 135 and 136;

Figure 18 shows the tracks (access) of the first track and the second track on the optical disc;

Fig. 19 shows another track path of the first track and the second track on the optical disc;

Fig. 20 shows an example of a sector ID in which sector address information of the first track or the second track is recorded.

Detailed ways

Hereinafter, optical information recording/reproducing apparatuses according to various embodiments of the present invention will be described with reference to the accompanying drawings.

FIG. 1 shows a sector format of a land/groove recording optical disc according to a first embodiment of the present invention. Fig. 1(a) shows a sector format of a groove track as a first track. Sector 13 is composed of sector ID field ID1, data field DF, gap G1 and buffer field B1. Among them, in the sector ID field ID1, record the address signals A1 and A2 for the sector and modulated by the first modulation method; in the data field DF, use the second modulation method to record data; in the gap G1 there is no recording signal; and the buffer field B1 is used to buffer the rotation change of the disc and each time period. The data field DF includes a synchronization clock field VFO14 for synchronizing the clock signal, a data identifier SYN15 indicating the start of data, and user data and an error correction code 16 .

Fig. 1(b) shows a sector format of a land track as a second track. Sector 17 is composed of sector ID field ID2, data field DF, gap G2 and buffer field B2. Wherein, in the sector ID field ID2, the address signals a1, a2 and a3 for the sector are recorded with the second modulation method; in the data field DF, data is recorded with the second modulation method.

The data field DF has the same structure as the data field of Fig. 1(a). For example, use a digital modulation method PE (phase encoding) modulation as the first modulation method; another example, use another digital modulation method (2-7) RLL (run length limited) modulation as the second modulation Way. Since the DR (density ratio) of these two modulation methods is 1:3, and the reproduction of the RU signal requires a PLL (Phase Loop) circuit, the address signal is written into ID1 twice and ID2 three times, so sectors 13 and 17 have the same length.

ID1 and ID2 of sectors 13 and 17 are arranged along the radial direction of the optical disc, and a crosstalk of about -15 dB is generated between the two ID fields. Since the modulation methods of ID1 and ID2 are different from each other, the ID1 and ID2 signal reproduction circuits work in different modulation methods. However, each ID signal can be reproduced normally without being affected by crosstalk.

In FIG. 1, only the ID fields of the groove track and the land track are conditioned on different modulation schemes. On the other hand, the ID field and the data field can also be conditioned on the recording of different modulation schemes. The same effect can be obtained when at least the ID field located between the ID field and the data field is conditioned on recording of different modulation schemes.

Fig. 2 shows a sector format of a land/groove recording optical disc, which is a second embodiment of the present invention.

The same reference numerals in FIG. 2 as in FIG. 1 denote blocks having the same functions. In FIG. 2, ID3 and ID4 represent sector identification fields in which address information is recorded.

The sector format of a groove recording track shown in FIG. 2(a) is the same as that of a land recording track shown in FIG. 2(b). In the sector identification fields ID3 and ID4, signals modulated by the same modulation system but opposite in polarity are recorded. In particular, in ID3, as shown in FIG. 2(a'), channel bits "1" of the modulated signal are recorded on the land layer and "0" are recorded on the groove layer. In ID4, as shown in FIG. 2(b'), channel bits "1" are recorded on the groove layer and "0" are recorded on the land layer.

ID3 and ID4 of sectors 13 and 17 are arranged along the radial direction of the disc, and there is about -15dB crosstalk between the two ID fields. However, since the polarities of the ID signals in the lands and grooves are reversed, the ID signal reproduction circuit can only read the ID signals that have undergone a signal inversion process with respect to the respective tracks, so that the respective ID signals can be reproduced normally without will be affected by crosstalk.

Fig. 3 shows a sector format of a land/groove recording optical disc according to a third embodiment of the present invention. Fig. 3(a) shows a sector format of a groove track. Track 18 is divided into a plurality of sectors 19 . Fig. 3(b) shows a sector format of a land track. Track 20 is divided into a plurality of sectors 21 . FIG. 3(c) shows the format of the sector ID field ID of sectors 19 and 21. FIG. Each sector ID field includes VFO2 for clock synchronization, address character AM to indicate the beginning of address information, track address TA, sector address SA, land/groove identification signal 22, error detection signal CRC, and Postamble PA. In Fig. 3, the initial sector 19 of the groove recording track 18 is shifted a distance G3 from the initial sector 21 of the land recording track 20 in position, like this, the ID of the two sectors will not be opposite to each other on the track direction. overlapping. The land/groove identification signal 22 of each sector indicates whether the corresponding ID belongs to the groove track 18 or the land track 20, respectively. For example, when the ID belongs to the groove track 18, it is recorded as "0"; when the ID belongs to the land track 20, it is recorded as "1".

Since the IDs of the tracks 18 and 20 are arranged along the radial direction of the optical disk, and the two are shifted by G3 in position, they will not be affected by crosstalk with each other. Even when crosstalk occurs, by checking the land/groove identification signal in the ID signal reproducing circuit, the ID signal of the track being traced by the light beam is allowed to be normally reproduced. Since the two ID signals are shifted by a distance in the track direction, the effect of conveniently forming pits in the ID field can be produced at the same time.

Fig. 4 is a diagram showing the signal arrangement of a land/groove recording optical disc according to a fourth embodiment of the present invention.

In FIG. 4, (a) shows the composition of each sector address signal used in this embodiment. The composition is the same as that shown in Fig. 3(c). FIG. 4(b) shows the relationship of the recording positions of the VFO2 field located at the start position of the ID signal of the groove track 23 and the land track 24, respectively. The recording dot 25 of the channel bit "1" of the address signal of the groove track 23 is formed corresponding to the horizontal position of the land 28, and the recording point 25 of "0" is formed corresponding to the horizontal position of the groove 29. The recording point 26 of the address signal of the land recording track 24 is formed as follows, the channel bit "1" corresponds to the horizontal position of the groove 29, and "0" corresponds to the horizontal position of the land 28. Also in the first and third embodiments, the recording points 25 and 26 can be formed in a manner similar to that described above. In this embodiment, the recording points 25 and 26 are recorded to be shifted by half of the period T of the maximum frequency of the address signal, or to form a grid pattern.

Since the recording points of the address signals of the recording tracks 23 and 24 are shifted by T/2 when they are arranged in the radial direction of the optical disk, the influence of crosstalk can be greatly suppressed. Even when the address signal is erroneously reproduced due to crosstalk, by checking the land/groove identification signal 22, the ID signal of the track traced by the current light beam can be normally reproduced.

In the above-mentioned first to fourth embodiments, the address signal may be composed of one of the following groups: track address TA and sector address SA; track identification signal 22, address information AM, and error detection signal CRC; track address TA, sector address SA, track identification signal 22, address information AM, and error detection signal CRC.

The optical discs described in the first to fourth embodiments are usually made such that the depth of the groove track is set to λ/(8n), where λ is the wavelength of the laser beam and n is the refractive index of the optical disc substrate.

5 is a block diagram showing an embodiment of an information recording/reproducing apparatus for recording information on and/or (reproducing) information from the optical disc of the present invention. The narration after this all is carried out for following situation, promptly respectively make recording track designating device CPU47, recording track searching device is made linear motor 34, and signal reproducing device is made as head amplifier 36, and address reproducing device is made as The sector ID reproducing circuit 40, the data recording/reproducing control means is set as the sector recording/reproducing control circuit 41, and the information recording/reproducing means is set as the data modulation and demodulation circuit 42.

In FIG. 5, 30 designates a disc to be stacked with a motor 31 to rotate. 32 designates the recording plane of the optical disc 30 . 33 designates the optical head for focusing the laser light on the recording plane 32 . 34 designates a linear motor (LM) for moving the optical head 33 to search for a target track as track search means. Reference numeral 35 designates a focus tracking control circuit, which includes the following components: focusing means for focusing control of the light beam of the optical pickup 33; tracking means for tracking control and track re-tracking. Reference numeral 36 designates a head amplifier functioning as signal reproducing means, which amplifies and outputs the track error signal n in the detection signal a of the optical head 33 and the reproduced signal c. Reference numeral 37 designates a binary encoding circuit for binary encoding a reproduced signal c. 38 designates a laser drive circuit for driving the semiconductor laser of the optical pickup 33 . 39 designates a linear motor control circuit which controls the linear motor 34 so that the optical head 33 finds the target track. Reference numeral 40 designates a sector ID reproducing circuit serving as address reproducing means, which outputs the sector address e of the track having the sector ID and the land/groove identification signal q from the output d of the binary encoding circuit 37. Reference numeral 41 designates a sector recording/reproduction control circuit serving as data recording/reproduction control means, which compares the track sector address e with the target sector address of that CPU data bus f to record or reproduce data, Check whether they match, and generate a write gate signal g and a read gate signal h for the sector. Reference numeral 42 designates a data modulation and demodulation circuit used as an information recording/reproducing apparatus, which digitally modulates coded data i by (2-7) RLLC (run length limited code) or the like, and outputs a modulated signal j, And demodulates the binary-coded reproduced signal d to output demodulated data k. Reference numeral 43 designates an error correction circuit which generates coded data i in which a correction code added to this data is to be recorded, which detects a code error in modulated data k and corrects the data. 44 designates a memory for temporarily storing data. 45 marks a computer host. 46 designates an interface IF to which a host computer 45 is connected via a SCSI (Small Computer System Interface) bus X. 47 designates a CPU of a microcomputer serving as track specifying means, which controls the entire information recording/reproducing apparatus. In Fig. 5, m marks a land/groove selection signal provided to the focus tracking control circuit 35 and the sector ID reproduction circuit 40 by the CPU 47 output, which selects the recording/reproduction of the land track and the recording of the groove track. Record/reproduce one of them.

FIG. 6 is a configuration diagram showing a tracking control unit of the focus tracking control circuit 35 in FIG. 5 . In the figure, 48 designates an inverter circuit for tracking error signal n. 49 designates a multiplexer MPX which selects a tracking error signal n or an inverted signal n' of the error signal based on a land/groove selection signal m. 50 designates a tracking servo circuit. p denotes an actuator driving signal for driving the tracking actuator of the optical pickup 33 . The land/groove select signal is switched and the tracking error signal n is inverted so that tracking is performed on the land track or the groove track.

7 is a diagram showing the structure of the sector ID reproduction circuit 40 used when the signal modulation method of the sector ID field of the land track is different from that of the groove track in the first embodiment of the optical disc shown in FIG. 1. In the figure, 51A designates an address reproducing circuit A for reproducing a groove track sector ID. 51B designates an address reproducing circuit B for reproducing the land track sector ID. 52 designates a multiplexer MPX which selects one of the reproduction address outputs e1 and e2 of the address reproduction circuits 51A and 51B in accordance with the land/groove selection signal m.

FIG. 8 is a diagram showing the configuration of a sector ID reproducing circuit 40 used when the modulation signals of the sector ID fields of the land and groove tracks in the optical disc according to the second embodiment of FIG. 2 have opposite polarities. In the figure, 53 designates an inverter circuit for inverting the binary-coded reproduced signal d. 54 designates a multiplexer MPX which selects the binary-coded reproduced signal d or the inverted signal d' of the reproduced signal on the basis of the land/groove select signal m. 55 designates an address reproducing circuit. q designates the land/groove identification signal.

In the circuit of Fig. 8, when the optical disc of the embodiment in Fig. 3 is to reproduce the IDs of the groove recording track 18 and the land recording track 20 recorded with the same modulation method, the land/groove selection signal m It is assumed that the multiplexer 54 should select the binary-coded reproduced signal d to identify the land by using the land/groove identification signal q and combining this circuit with the circuit of FIG. 9 which will be described below. track or groove track.

FIG. 9 is a diagram showing in detail the configuration of the sector recording/reproducing control circuit 41 used in the optical disc shown in FIGS. 3 and 4 . Among the figure, 56 marks a register that responds to the strobe signal s 1 to latch the target address of the CPU data bus f. 57 designates a comparison circuit A for comparing the output of a pair of registers 56 with the reproduced address e. 58 designates a comparison circuit B which compares the land/groove identification signal q with the land/groove selection signal m, and outputs a coincidence signal when the above two signals coincide with each other in the state where the comparison circuit A57 outputs a coincidence signal. . 59 marks a read/write gate signal generator, which will respond to the strobe signal s2 from the CPU data bus f latch into the read or write command output of the register 60 as data modulation when the comparison circuit B58 has an output. The write gate signal g or the read gate signal h of the demodulation circuit 42 .

The operation of the recording/reproducing apparatus configured as above to record and/or reproduce information on a double-sided optical disc will be described below.

The data recording operation will be described after this.

The computer host 45 outputs a write command to the SCSI bus x. CPU47 receives this command through IF46, and decodes it. The CPU 47 outputs a land/groove selection signal m according to whether the target track is a land track or a groove track, so that the optical head 33 performs focus tracking on a given track. As shown in Figure 6, the focus tracking control circuit 35 makes the tracking error signal n provided by the optical pickup 33 invert or in phase according to the land/groove selection signal m, and sends the tracking actuator coil of the optical pickup 33 An actuator drive signal p is provided. The focus tracking control circuit then provides a command to the linear motor drive circuit 39 to find the target track to drive the linear motor 34, so that the optical head 33 moves to the target track.

The data to be recorded provided by the host computer 45 is stored in the memory 44 . The error correction circuit 43 outputs coded data i in which an error correction code added to this data will be recorded.

The CPU 47 sends the recording sector address and the recording command to the sector recording/reproduction control circuit 41, which then compares the recording sector address with the address output e of the ID reproduction circuit 40. The write gate signal g is sent to the data modulation and demodulation circuit 42 when the address matches and a given sector is detected. The write gate signal g activates the data modulation and demodulation circuit 42 so that the coded data i is modulated by (2-7) RLL, and the modulated signal j is sent to the laser driving circuit 38 .

The optical head 33 records the modulated signal j into a sector of the recording plane 32 . The data recording operation described above can be repeated within a given number of sectors.

The data readout operation will be described hereafter.

The host computer 45 outputs a read command to the SCSI bus x. CPU47 receives order through IF46, decodes it. The CPU 47 outputs a land/groove selection signal m according to whether the target track is a land track or a groove track, so that the optical head 33 performs focus tracking on a given track. As shown in Figure 6, the focus tracking control circuit 35 makes the tracking error signal n provided by the optical read-write head 33 invert or in-phase according to the land/groove selection signal m, and sends the actuator drive signal p to the optical read-write The write head 33 tracks the actuator coil. The focus tracking control circuit then sends a command to seek the target recording track to the linear motor driving circuit 39 to drive the linear motor 34, so that the optical read-write head 33 moves to the target recording track.

The CPU 47 sends the read sector address and the read command to the sector recording/reproduction control circuit, which then compares the read sector address with the address output e of the ID reproduction circuit 40. When the address matches and the sector recording/reproducing control circuit 41 detects a given sector, the read gate signal h is sent to the data modulation and demodulation circuit 42 .

The data modulation and demodulation circuit 42 is activated in response to the read gate signal h, and demodulates the detection signal d detected by the optical head 33 to obtain reproduced data k. The reproduced data k is then stored in the memory 44 .

The reproduced data stored in the memory 44 is subject to error detection and correction by the error correction circuit 43, and then stored in this memory 44 again. The error-corrected reproduced data is sent to the host computer 45 through the interface 46 . The data readout operation described above can be repeated within a given number of sectors.

The operations of the ID reproducing circuit 40 and the sector recording/reproducing control circuit 41 will be described in detail while comparing them with the embodiment of the optical disc of the present invention to which these circuits are applied.

The ID reproducing circuit 40 applied to the optical disc (FIG. 1) of the first embodiment has the configuration shown in FIG. In the optical disk in FIG. 1 , the ID fields of the land track and the groove track are modulated and recorded by different modulation methods. Therefore, the first and second address reproducing circuits 51A and 51B in FIG. 7 perform reproducing operations on binary-coded reproducing data d at the same time. When the modulation method of the binary-coded reproduction signal d matches the modulation method of the first and second address reproduction circuits 51A and 51B, reproduction address signals e1 and e2 are output. The multiplexer 52 selects a certain address signal e1 or e2 corresponding to the land/groove selection signal m, and then outputs it as the reproduction address signal e.

The ID reproducing circuit 40 applied to the optical disc (FIG. 2) of the second embodiment has the constitution shown in FIG. 8, and the sector recording/reproducing circuit 41 has the constitution shown in FIG.

In the optical disc of FIG. 2, the address signals of the ID fields of the land track and the groove track are recorded with opposite polarities to each other. In FIG. 8, the multiplexer 54 selects the binary-coded reproduced signal d or the binary-coded reproduced signal d' inverted by the inverter circuit 53 according to the land/groove selection signal m. The selection signal is demodulated by the address reproducing circuit 55, and further outputs a reproducing address signal e and a land/groove identifying signal q to the sector recording/reproducing control device 41 of FIG.

In FIG. 9, the target address of the CPU data bus f is latched into the register 56 in response to the pass-through signal s1, and compared with the reproduced address signal e in the comparing circuit 57. The land/groove identification signal q is compared with the land/groove selection signal m. The write command or read command of the CPU data bus f is latched into the register 60 in response to the strobe signal s2, and the output of the comparison circuit 58 is ANDed to output the write gate signal g or the read gate signal h. The write gate signal g or the read gate signal h is sent to the data modulation and demodulation circuit 42 to start data modulation or data demodulation.

The ID reproducing circuit 40 applied to the optical disc (FIG. 3) of the third embodiment has the constitution shown in FIG. 8, and the sector recording/reproducing circuit 41 has the constitution shown in FIG.

In the optical disc of FIG. 3, the address signals of the ID fields of the land track and the groove track are recorded in such a manner that the ID fields do not overlap each other in the track direction. The reproduction of the address, and the generation of the write gate signal or the read gate signal, except that the multiplexer 54 in Figure 8 always selects the reproduction signal d of the binary code, the others are all carried out in the same manner as for the optical disc of the second embodiment. .

The ID reproducing circuit 40 applied to the optical disc (FIG. 4) of the fourth embodiment has the constitution shown in FIG. 8, and the sector recording/reproducing circuit 41 has the constitution shown in FIG.

In the optical disc of FIG. 4, the address signals of the ID fields of the land track and the groove track are recorded in such a manner that the recording points are shifted by T/2 in the track direction or form a lattice pattern. The reproduction of the address, and the generation of the write gate signal or the read gate signal, except that the multiplexer 54 in Figure 8 always selects the reproduction signal d of the binary code, the others are all carried out in the same manner as for the optical disc of the second embodiment. .

According to the above configuration, while the recording density of the optical disc with land/groove recording is increased to a level higher than that of the prior art, by making the modulation method and/or signal polarity different from each other, or changing the ID position or recording point phase, thus Compared with the prior art, the crosstalk between adjacent land and groove recording tracks is reduced, and data or ID signals can be read with a lower bit error level without being affected by the crosstalk.

In order to achieve the purpose of the present invention, it can also be implemented by combining the optical discs of the above-mentioned first to fourth embodiments.

Hereinafter, an embodiment of the second invention will be described with reference to the drawings.

11 and 12 are block diagrams showing the constitution of an embodiment of an information recording/reproducing apparatus applicable to the optical disc of the present invention. In FIGS. 11 and 12 , 101 denotes a disc attached to a motor 102 . 102 denotes a motor for rotating the optical disc 101 . 103 denotes a recording plane of the optical disc 101 . 104 denotes an optical read/write head for focusing a laser beam on the recording plane 103 . 105 denotes a linear motor (LM) for moving the optical head 104 to search for a target track. 106 represents a focus tracking control circuit, which completes the focusing/tracking control of the light beam and re-tracks the recording track of the optical pick-up head 104, and 107 represents a read-write head amplifier, which adds and subtracts the detection signal of the optical pick-up head 104 To obtain focus error signal b, tracking error signal c and reproduction signal d. 108 denotes a binary encoding circuit for binary encoding a pair of reproduced signal d to obtain binary encoded signal e. 109 designates a laser drive circuit for driving the semiconductor laser of the optical head 104 . 110 denotes a linear motor control circuit which controls the linear motor 105 so that the optical head 104 finds the target track. Reference numeral 111 denotes a sector ID reproducing circuit which reads out a track address and a sector address f, and a track identification signal g of the sector ID from the binary coded signal e. Reference numeral 112 represents a read/write gate signal generator, which compares the track address and sector address f with the target sector address h of the CPU data bus to record or reproduce data, and generates a write gate for the sector Signal i and readout gate signal j. Reference numeral 113 denotes a data modulation and demodulation circuit which digitally modulates coded data k by using (2-7) RLLC (Run Length Limited Code) etc., outputs modulated signal m, and also demodulates binary coded reproduced signal e to output Demodulate data n. Reference numeral 114 denotes an error correction circuit which generates coded data k in which an error correction code added to the data is recorded, and detects and corrects a code error in demodulated data n. 115 denotes a memory for temporarily storing data. 116 represents a computer host. 117 denotes an interface IF to which the computer host 116 is connected via a SCSI (Small Computer System Interface) bus x. 118 denotes a microcomputer (CPU) which controls the entire information recording/reproducing apparatus. 119 denotes a disc management information for storing the optical disc 101, defect list information and the like. 128 denotes a bit error detection circuit, which counts the number of bit errors detected by the error correction circuit for each sector. 129 denotes a work area. Reference numeral 120 denotes a track specifying circuit which outputs a track selection signal p which is output from the CPU 118 to the focus tracking control circuit 106 and the sector ID reproduction circuit 111, or selects the recording of the first track. /reproduction, to record data on the grooves, or select recording/reproduction of the second track, to record data on the lands.

In the focus tracking control circuit 106, 121 denotes an inverter circuit for the tracking error signal c. 122 denotes a multiplexer (MPX) which selects a tracking error signal n or an inverted signal n' of the error signal based on a track selection signal p. 133 denotes a focus tracking servo circuit. q represents an actuator driving signal for driving the tracking actuator of the optical pickup 104 . The tracking error signal c is inverted according to the track selection signal p to track the first track or the second track.

In the read/write gate signal generator 112, 124 denotes a register for latching the target address of the CPU data bus h. 125 denotes a comparator circuit which compares the output of the register 124 with the reproduction address f, and also compares the track identification signal g with the track designation signal p. 126 denotes a register for latching a read or write command from the CPU data bus h. 127 represents a gate signal generator, which responds to the output of the comparator circuit 125 or the output of the register 126, and outputs a write gate signal i or a read gate signal j to the data modulation and demodulation circuit 113 to start data modulation or data demodulation.

The memory 119a reads out the data of the object sector in the disk management area of the optical disc 101 as required, or reads out and stores a defect list table area address, a spare area address, a data recording area address, defect management identification information, and capacity block Management method identification information. The cpU 118 controls the data recording of the first and second tracks of the optical disc 101 and the replacement process of defective sectors according to the contents of the memory 119 . Reference numeral 119b represents a memory for recording defect list information, and it includes a first storage device for storing the content of the defect list area of the first track, and a second storage device for storing the content of the defect list area of the second track. storage device. 119c denotes a work area for executing a defect replacement process.

Fig. 13 is an appearance view of an optical disc according to an embodiment of the present invention in which the first recording track records data on grooves and the second recording track records data on lands. In Fig. 13, the ID signal is not shown. Fig. 13(a) is a plan view of the first and second recording tracks, and Fig. 13(b) is a cross-sectional view of part A-A' in Fig. 13(a).

In Fig. 13, 130 denotes the first track of the groove-shaped spiral guide. 131 denotes a second track composed of lands sandwiched by the first track 130 . 132 denotes the substrate of the optical disk. 133 denotes a recording film. 134 denotes a light spot for recording information on the first and second recording tracks or reproducing information from the first and second recording tracks. The first track is a groove of depth d. In order to suppress the amplitudes of the tracking signal and the reproduced signal, and to suppress the degree of crosstalk between the first and second tracks, the depth d is set to about λ/6n.

Fig. 14 is a diagram showing areas of the optical disc according to the first embodiment of the present invention. In FIG. 14, (a) shows a recording plane 1100 composed of the first track, and (b) shows a recording plane 1101 composed of the second track.

Reference numerals 35 and 36 denote disc management areas formed in recording planes 1100 and 1101 of the first and second tracks of the optical disc 101, respectively. 137 marks the defect list area for managing the defective sector and the replacement sector of the defective sector. 138 and 139 denote data recording areas for recording data. 140 denotes a spare area recorded instead of a defective sector. The defect list area 137 is formed on one side of the optical disc 101, or in the first recording track in the embodiment of FIG. Defective sectors are collectively replaced in the spare area 140 .

As described above, the present invention concentrates on recording planes 1100 and 1101 . Therefore, it is easy to manage the data recording areas 138 and 139 as one capacity block, and effectively use the spare area. In the present invention, a single defect directory table area is used. Therefore, even if the access is over the first and second tracks, it is not necessary to read from the defect list area every time, so that the processing can be performed more quickly.

Fig. 15 is a diagram showing areas of an optical disk according to a second embodiment of the present invention.

In FIG. 15, (a) shows a recording plane 1100 composed of the first track, and (b) shows a recording plane 1101 composed of the second track. In the first and second tracks of the optical disc 101 are formed disc management areas 35 and 36, data recording areas 138 and 139 for recording data, and spare areas 141 and 142 for recording instead of defective sectors. The defect list area 137 is formed on one side of the optical disc 101, or in the first track in the embodiment of FIG. 15 .

Defective sectors in the data recording area 138 are replaced in the spare area 141 , and those in the data recording area 139 are replaced in the spare area 142 .

As described above, according to the present invention, a defective sector detected during execution of recording onto the first or second track is replaced in the spare area 141 or 142 of the track. Thus, there is no need to change the track selection from the first track (or the second track) to the second track (or the first track). Track selection is necessary only when the polarity of the tracking error signal c is inverted by the tracking circuit 106, so that the time it takes to retrack to the target track is unnecessary. In other words, the replacement process can be performed quickly.

Fig. 16 is a diagram showing areas of an optical disk according to a third embodiment of the present invention.

In FIG. 16, (a) shows a recording plane 1100 composed of the first track, and (b) shows a recording plane 1101 composed of the second track. In the figure, 35 and 36 denote disc management areas formed in the first and second tracks of the optical disc 101, respectively. 137 and 143 indicate the defect list area. 138 and 139 denote data recording areas for recording data. 141 and 142 denote spare areas for recording instead of defective sectors.

Defective areas in the data recording area 138 are replaced in the spare area 141 , and those in the data recording area 139 are replaced in the spare area 142 .

As mentioned above, according to the present invention, the replacement operation process of the defective sector of the recording plane 1100 is carried out by combining the defect list area 137 and the spare area 141, and the recording plane 1101 is by combining the defect list area 143 and the spare area 142 conducted. There is thus no need to change tracks between the first and second tracks, and therefore no time spent retracing. Since the spiral track access can be efficiently utilized, the time to wait for the rotation of the disc due to track change can be shortened, thereby allowing the replacement process of the defective area to be performed quickly.

The data recording areas 138 and 139 can be guaranteed to have the same capacity in the recording planes 1100 and 1101 . Therefore, the system design of the system using the optical disc can be simplified. Since the recording planes 1100 and 1101 are independently processed for defects, the structure of the data to be written into the data recording areas 138 and 139 can be easily managed when they are divided into multiple capacity blocks.

FIG. 17 shows an example of management information to be recorded in the disc identification areas 35 and 36. As shown in FIG. In Fig. 17(a), 144 denotes a disk management flag. 145 denotes an address of a defect list table area. 146 denotes a spare area address. 147 denotes a data recording area address. 148 represents a defect management method identification. 149 represents a capacity block management identifier. In Fig. 17(b), 150 denotes a disk management ID. 151 denotes an address of a defect list table area. 152 denotes a spare area address. 153 denotes a data recording area address. 154 represents a defect management method ID. 155 represents a capacity block management identifier.

Disk management flags 144 and 150 indicate that the respective sectors are disk management information areas. The addresses 145 and 151 of the defect list area indicate the positions and sizes of the defect list areas 137 and 143 of the recording planes 1100 and 1101, respectively. The spare area addresses 146 and 152 indicate the locations and sizes of the spare areas 140, 141, and 142 of the recording planes 1100 and 1101, respectively. The data recording area addresses 147 and 153 indicate the positions and sizes of the data recording areas of the recording planes 1100 and 1101, respectively. The defect management method identifiers 148 and 154 designate the defect management methods shown in FIGS. 14 to 16 . The capacity block management flags 149 and 155 indicate the structure of the capacity blocks recorded on the recording planes 1100 and 1101, and also record the number of capacity blocks and the allocation information of the data recording areas 138 and 139 constituting each capacity block.

18 to 20 are track access diagrams showing an embodiment of track addressing in an optical disc 101 in which the first and second tracks are spiral tracks.

In the figure, 156 denotes a first track, 157 denotes a second track, 158 denotes a recording plane of the first track, and 159 denotes a recording plane of the second track.

In FIG. 18, the tracks to be accessed, such as the first track and the second track, are switched every time the disc is rotated, that is, the tracks are accessed in the order of 11'22'3.... In the optical disc 101, the first and second recording tracks can be accessed as one capacity block, and the first and second recording tracks 156 and 157 are spiral recording tracks. Therefore, when it is necessary to record data of a larger capacity block, there is no need to search for a recording track, and data recording or reproduction can be performed rapidly as long as the polarity of the tracking signal is switched.

FIG. 19 is a track access diagram showing sequential access to the first and second tracks 156 and 157. In FIG. During data recording or reproduction, tracks 123...n are accessed in the first track 156 of the recording plane 158, and tracks 1'2'3'...n' are accessed in the second track 157 of the recording plane 159 . This access achieves the effect that when it takes a long time to switch between the tracking of the first and second tracks, the average access time can be shortened, and the delay between the first and second tracks is eliminated. The time it takes to wait for the disc to rotate to the target sector for a track change.

FIG. 20 shows an example of a sector ID in which the sector address information of the first and second tracks is recorded. In the figure, TA represents a track address, SA represents a sector address, and 160 represents track identification information indicating the first and second tracks newly added to the most significant track address. The track identification information 160 is a track identification signal g of the most significant bit of the track, which indicates whether the track is the first track or the second track.

Referring now to Fig. 14, the operation of the optical disk recording/reproducing apparatus for recording or reproducing information on the thus constituted optical disk will be described.

The initialization operation of the information recording/reproducing apparatus is described thereafter.

The computer host 116 outputs a read command to the ScSI bus x for reading the disk management areas 35 and 36 . The CPU 118 receives the command through the IF 117, decodes it, and outputs a track selection signal p (for example, groove track selection for selecting the first track) to the track selection circuit 120 to access the disc management information area 35. In response to the track specifying signal p, the multiplexer 122 sends a tracking error signal c to the focus tracking circuit 123, thereby tracking the first track. The linear motor driving circuit 110 then drives the linear motor 105 so that the optical head finds the initial track of the disk management area 35 .

The CPU 118 places the read sector address in the register 124 of the read/write gate signal generator 112 and places the read command in the register 126 . In the read/write gate signal generator 112, the comparator circuit 125 compares the read sector address of the register 124 with the address output f of the ID reproduction circuit 111, and also compares the track specifying signal p with the track identification signal g compared to. The gate signal generator 127 decodes the coincidence output and the output of the register 126 , and sends the readout gate signal j to the data modulation and demodulation circuit 113 . The data modulation and demodulation circuit 113 is activated by the readout gate signal j, demodulates the reproduced signal e of the disk management area 35, sends the demodulated data n including the disk management information and defect list information to the memory 115, and sends These data are stored in the memory. The demodulated data n stored in the memory 115 undergoes error detection and correction in the error correction circuit 114 , and then is stored in the memory 115 . The CPU 118 reads out the error-corrected reproduced data, and writes the data into the memory 119 .

Then, the CPU 118 sets the track selection signal p to land track selection, and writes the disk management information 2 of the disk management area 36 of the second track into the memory 119 .

Therefore, the CPU 118 understands the capacity block management method of the optical disc 101, the defect management method, the defect list area, the spare area, the data recording area, and the defect list information, and executes data recording and reproduction mentioned below.

Next, the data recording verification operation process performed on the data recording area 138 of the optical disc of FIG. 14 will be described.

The computer host 116 writes the write command to the ScSI bus x. The CPU 118 receives the command through the IF 117, decodes it, and checks whether the target sector is a defective sector based on the defect list information stored in the memory 119. If the sector is not a defective sector, the track selection signal is directed to the first or second track according to the sector. If the sector is a defective sector, the track selection circuit 120 is configured to select the second track with the spare area 140 . In response to the track specifying signal p, the tracking error signal c or the inverted tracking error signal c' is sent to the focus tracking circuit 123 to track the first track or the second track. The linear motor drive circuit 110 drives the linear motor 105 to move the optical head 104 to the target recording track.

Once the data to be recorded provided by the host computer 116 is stored in the memory 115, it is converted into coded data k by the error correction circuit 114, wherein the error correction code added to the data will be recorded.

The CPU 118 sends the recording sector address to the register 124 of the read/write gate signal generator 112 according to the defect list information, and sends the write command to the register 126 . The read/write gate signal generator 112 compares the recording sector address of the register 124 with the address output f of the ID reproduction circuit 111. Simultaneously, the comparator circuit 125 compares the track designation signal p of the track designation circuit 120 with the track identification signal g of the ID reproduction circuit 111 . The gate signal generator 127 sends the write gate signal i to the data modulation and demodulation circuit 113 in response to the coincidence output of the comparator circuit 125 and the write/read command of the register 126 . The data modulation and demodulation circuit 113 is activated by the write gate signal i, the coded data k is modulated by (2-7) RLLc, and the modulation signal m is sent to the laser driving circuit 109 . The optical head 104 records the modulated signal m to a target sector of the recording plane 103 . The above data recording operation is repeated within a given number of sectors.

When the data recording is completed, the CPU 118 sequentially reads out the recorded sectors, and checks the number of bit errors of the demodulated data. If the number of detected bit errors exceeds the specified index, the sector is replaced and recorded in the spare area 140 . More specifically, the host computer 116 sends an order to read the recording sector, and the CPU 118 makes the optical head 104 move to the recorded track as in the above-mentioned data recording mode. The CPU 118 sends the read sector address to the register 124 of the read/write gate signal generator 112, and sends the read command to the register 126. In the read/write gate signal generator 112, the comparator circuit 125 compares the read sector address of the register 124 with the address output f of the ID reproduction circuit 111, and also compares the track specifying signal p with the track identification signal g Compared. The gate signal generator 127 decodes the coincidence output and the output of the register 126 , and sends the readout gate signal j to the data modulation and demodulation circuit 113 . The data modulation and demodulation circuit 113 is activated by the read gate signal j, demodulates the reproduced signal e of the recording plane 103 provided by the optical head 104, sends the demodulated data n to the memory 115, and stores the data in the memory. The demodulated data n stored in the memory 115 is subjected to error detection and correction in the error correction circuit 114 . The number of bit errors detection circuit 128 counts the number of bit errors detected for each sector. The CPU 118 monitors the number of bit errors in the bit error number detection circuit 128 to check whether the number exceeds the index number. A sector whose number of bit errors exceeds the index is judged as a defective sector and is replaced in the spare area 140 .

To record data in the spare area 140 in place of a defective sector, a write command is issued. The CPU 118 outputs the track designation signal p for selecting the second track to the track selection circuit 120 . The multiplexer 122 sends the inverted tracking error signal c' to the focus tracking circuit 123 to track the second track. Data is then recorded to the spare area in the same manner as described above for data recording. The addresses of the defective sector and the replacement sector of the data are recorded in the defect list area 137 as a column combination.

For the spare sector and the defect list sector, replace the defective sector in the same manner as above.

In the case where spare areas are respectively formed in the first and second tracks as shown in FIG. 15, the detected defective sector is replaced in the spare area 141 or 142 of the track to which the defective sector belongs. In the case where defect list areas 137 and 143 are formed in the first and second tracks respectively as shown in Figure 16, the sector address list used in the defect replacement process is recorded to the defect list to which the defective sector belongs. table area. The above-mentioned data recording and replacement of defective sectors are all carried out according to the contents of capacity block management flags 149 and 155 and defect management method flags 148 and 154 .

Referring to Fig. 14, data recording to the data recording area 138 will be described.

When the host computer 116 outputs a read command, the CPU 118 decodes the command, and checks from the defect list stored in the work area 119c of the memory 119 whether the target sector is a defect sector. If the sector is a defective sector, the track selection circuit 120 is set to select the second track with the spare area 140 . In response to this track specifying signal p, the tracking error signal c or the inverted tracking error signal c' is sent to the focus tracking circuit 123 to track the first track or the second track. The linear motor drive circuit 110 drives the linear motor 105 to move the optical head 104 to the target recording track.

The CPU 118 sends the read sector address to the register 124 of the read/write gate signal generator 112 according to the defect list information, and sends the read command to the register 126 . In the read/write gate signal generator 112, the comparison circuit 125 compares the read sector address of the register 124 with the address output f of the ID reproduction circuit 111, and compares the track specifying signal p with the track identification signal g . The gate signal generator 127 decodes the coincidence output and the output of the register 126 , and sends the readout gate signal j to the data modulation and demodulation circuit 113 . The data modulation and demodulation circuit 113 is activated by the read gate signal j, demodulates the reproduced signal e of the recording plane 103 sent by the optical head 104, sends the demodulated data n to the memory 115, and stores the data in the memory. The demodulated data n stored in the memory 115 undergoes error detection and correction in the error correction circuit 114, and is stored in the memory 115 again. The error-corrected reproduced data is sent to the host computer 116 via the interface 117 . The above data readout operation is repeated within a given number of sectors.

In the case where data recording areas 138 and 139 or spare areas shown in FIG. 15 are respectively formed on the first and second recording tracks, or the defect list areas 137 and 143 shown in FIG. 16 are respectively formed on the first and second recording tracks In the case of reading, the track selection signal p is switched by the track selection circuit 120. The defect management method and capacity block management are performed according to the content of defect management method identifiers 148 and 154 and capacity block identifiers 149 and 155 .

As described above, according to the present invention, data recording and reproduction, and defect replacement processing can be performed on an optical disc composed of first and second tracks formed on the same recording plane, and thus, compared with the prior art, both Double the data capacity blocks for recording.

The disk management area is created during disk initialization. Next, the initialization method of the optical disc shown in Fig. 16 will be described.

When the first track 130 is traced by the light spot according to the track selection signal p, a test signal is recorded, and then read out for verification, thereby detecting a defective sector. Then, the track selection signal p is inverted to detect a defective sector in the second track 131 . According to the capacity and quality data of the optical disc 101, the CPU 118 ensures that the size of the defect list area 137 and 143 meets the replacement quantity of defective sectors, and records the address and size of the list area, the address and size of the spare area 141 and 142, and The addresses and sizes of the data recording areas 138 and 139. In the defect list area 137 , there are recorded replacement lists of defective sectors in the recording plane 1100 of the first recording track 130 and the recording plane 1101 of the second recording track 131 . Defect management method information 148 and 154, and capacity block identification information 149 and 155 are recorded in the disk management information areas 35 and 36 according to instructions from the computer host 116.

Of course, the above optical disk embodiments can be combined appropriately, which is very important.

According to the above description, it is clear that according to the present invention, data recording and reproduction can be performed on an optical disc composed of first and second recording tracks formed on the same recording plane, and defect replacement processing can be performed rapidly on this, thereby Compared with the prior art, the capacity can be greatly improved.

Claims (2)

1. the method for an initialization CD, in order to pass through it by optical disc replay information, described CD comprises first recording channel of typing and/or information reproduction, and second recording channel of typing and/or information reproduction, described first recording channel and second recording channel form on same record surface, and described first recording channel is a groove shape, and described second recording channel is the piston ring land shape that is sandwiched between described first recording channel, it is characterized in that

In the process of the described CD of initialization:

Capacity block is managed identification record in the CD managing district of described first recording channel and second recording channel, and the expression of described capacity block management sign is by the capacity block structure of described first recording channel and second recording channel record and reproduction data.

2. the method for initialization CD as claimed in claim 1 is characterized in that,

Each described first recording channel and second recording channel include interblock and described CD managing district;

Described CD managing district comprises a capacity management district, has wherein write down described capacity block management identification information.

Images