KR0166986B1 - Optical disc and information recording/reproducing apparatus - Google Patents

Abstract

The present invention relates to a high-density optical disc in which information is recorded and reproduced for a land portion and a groove portion of a track, and an information recording and reproducing apparatus for recording and reproducing information for the optical disc, wherein the recording density is increased and the crosstalk between tracks is reduced. It is an object of the present invention to provide an optical disc and an information recording and reproducing apparatus which can be used. In the configuration, for an optical disc having a home recording track and a land recording track on the same surface, sectors 13 and 17 of these tracks are provided. The ID reproducing circuit reproduces the binarization based on the signal detected from the optical disc by the multiplexer so that the ID signals ID1, ID2 and the ID signals ID1, ID2 and the data signal DF are recorded by different modulation schemes. The reproduction address signal corresponding to the land home selection signal output from the CPU among the reproduction address signals output from the address reproduction circuit corresponding to the modulation method of the signal. An information recording and reproducing apparatus configured to select and output a call is characterized by recording and reproducing information of an optical disc.

Description

Optical disc and information recording and reproducing device

1 is a sector format diagram of an optical disc according to a first embodiment of the present invention.

2 is a sector format diagram of an optical disc according to a second embodiment of the present invention.

3 is a sector format diagram of an optical disc according to a third embodiment of the present invention.

4 is a format diagram and layout diagram of an ID signal of an optical disc according to a fourth embodiment of the present invention.

5 is a configuration diagram of an embodiment of an information recording and reproducing apparatus applied to the optical disk of the present invention.

6 is a configuration diagram of one embodiment of the focus tracking control circuit portion of the embodiment.

7 is a configuration diagram of one embodiment of a sector ID reproducing circuit portion of the embodiment.

8 is a configuration diagram of another embodiment of the sector ID reproducing circuit portion of the embodiment.

9 is a configuration diagram of an embodiment of the sector recording and reproducing circuit portion of the embodiment.

10 is an explanatory diagram of information recording of an optical disc of a conventional example.

* Explanation of symbols for main parts of the drawings

13: Sector 14: Synchronous Clock Area (VFO)

15: data mark (SYN) 16: error correction code

17: Sector 18: Track

19: multiple sector 20: track

21: Multiple sectors 22: Land record identification code

23: home recording track 24: land recording track

25: recording feet of 1: 26: recording feet

28 land part 29 home part

31: motor 32: recording surface

33: optical head 34: linear motor

35 focusing means 36 head amplifying circuit

37: binarization circuit 38: laser drive circuit

39: linear motor control circuit 40: sector ID reproduction circuit

41: sector recording / reproducing circuit 42: data modulation / demodulation circuit

43: error correction circuit 44: memory

45: host computer 46: interface

47: microcomputer CPU 48: polarity inversion circuit

49: multiplexer (MPX) 50: tracking servo circuit

51a: address reproducing circuit (A) 51b: address reproducing circuit (B)

52: MPX 53: Inverting circuit

54: MPX 55: Address Regeneration Circuit

56: register 57: comparison circuit (A)

58: comparison circuit (B) 59: R / W gate generation circuit

60: register

The present invention relates to a high-density optical disc in which information is recorded and reproduced for the land and groove portions of a track, and an information recording and reproducing apparatus for recording and reproducing information for the optical disc.

An optical disc is a high density memory which has a large capacity, can record and reproduce in a non-contact state, and can exchange media.

The performance of a typical optical disk is about 300 nm to 500 MB / plane for a 130 nm disk and about 128 nm to 250 MB for a 90 nm disk using an optical head of laser wavelength 830 nm and lens NA 0.5. For multimedia applications, high-density recording and reproducing technology using short wavelength lasers of 680 nm to obtain capacities of two to four times the capacity has been studied.

10 is a plan view (top view) and a sectional view (bottom view) of a conventional example of a continuous servo track format.

FIG. 10 (a) is a continuous servo track employed in a conventional 130 mm or 90 mm optical disc, the track having a depth λ / (8 · n) (λ is a wavelength of the laser, n being formed on the transparent substrate 1). The refractive index of the substrate 1. Hereinafter, the pits 4 and the recorded recording marks 5, which are made up of grooves (grooves) 2 of the same type, and which are sector identification (ID) signals are sandwiched by the tracks. The pit 4 of the ID signal is an uneven pit of a phase depth of λ / (4 · n).

The track pitch is selected at approximately lambda / NA obtained as the laser wavelength lambda and the lens opening NA. In the conventional disc, in order to leave the land portion between the groove portion 2 and the pit portion 4 of the ID signal, it is difficult for the disk forming method to have a track pitch of 1.3 m or less.

In FIG. 10B, a track is formed in the groove portion 6 and the land portion 7 having a phase depth of λ / (8 · n), and the pit 8 and the data signal, which are ID signals, are recorded. The mark 9 is an example of a home recording track format in which the marks 9 are recorded inside the groove 6 together. Since the home recording track has a track structure consisting of a simple groove portion 6, a disc having a track pitch of 1 m or less is easily produced.

FIG. 10C shows a signal 12 for the land portion 11 in a home recording track in which the width of the groove portion 10 having a depth of approximately λ / (8 · n) is 1/2 of the track pitch. This is an example of a land home record for recording. In theory, this land groove recording can realize the density of the surface recording twice as much as the land recording shown in Fig. 10A.

In general, when the track pitch decreases, there is a problem in crosstalk of signals recorded in adjacent tracks, cross-erasing for erasing signals of adjacent tracks due to data recording, and safety of tracking servos.

Regarding the stability of the tracking servo, in the land recording track 10 corresponding to the land home recording in FIG. 10 (c), when the track pitch is λ / NA half, and λ = 830 nm and NA = 0.5, Even if the track pitch for recording a signal is 0.8 μm, the tracking servo may only track at a track pitch of 1.6 μm consisting of a groove portion or a land portion, so that the tracking can be stably performed by the conventional three-beam method or the push-pull method.

However, even in the land-home recording recorded as described above, when it is desired to increase the recording density by narrowing the track pitch, there is a problem of crosstalk between the track of the groove 11 and the track of the land 10. do.

In other words, when an optical head having a laser wavelength lambda = 830 nm and lens opening NA = 0.5 is used, crosstalk is -30 to -35 dB at a track pitch of 1.6 μm, and is -15 to -20 dB at a track pitch of 0.8 μm. There is a problem that normal ID signal reproduction or data signal cannot be reproduced.

In particular, playback errors such as error reproduction of the ID signal caused by crosstalk on the ID signal and error reproduction of the ID signal from adjacent tracks make it difficult to identify the target track at the time of track retrieval. In the case of recording in sectors, even if there is an ID signal leakage from an adjacent track, there is a problem in that the data is reproduced normally and recorded at the wrong sector position.

The present invention solves the above problems, can increase the recording density compared with the conventional one, and can reduce the crosstalk between the tracks of the land and groove portions, and the crosstalk between the tracks of the land and groove portions. It is an object of the present invention to provide an optical disc and an information recording and reproducing apparatus which can prevent errors in recording and reproducing of ID signals and data signals.

An optical disc according to the first aspect of the present invention is an optical disc having a recording surface comprising a spiral first track and a spiral second track, wherein information is recorded and reproduced for the first and second tracks. The track is formed in a groove shape, the second track is formed in a land shape between adjacent first tracks, and the first and second tracks record information by different modulation methods. .

An optical disc according to the second aspect of the present invention is an optical disc having a recording surface composed of a spiral first track and a spiral second track, wherein information is recorded and reproduced for the first and second tracks. The track is formed in a groove shape, the second track is formed in a land shape between adjacent first tracks, and the first and second tracks record an address signal in which address information is recorded in the same modulation scheme. And the address signal of the first track is opposite polarity to that of the second track.

An optical disc according to the third aspect of the present invention is an optical disc having a recording surface comprising a spiral first track and a spiral second track, wherein information is recorded and reproduced for the first and second tracks. The track is formed in a groove shape, and the second track is formed in a land shape between adjacent first tracks, and the first and second tracks record an address signal in which address information for identifying the track is recorded. And recording so that address signals of adjacent tracks which are the first and second tracks do not overlap in the radial direction.

An optical disc having a recording surface comprising a spiral first track and a spiral second track according to a fourth aspect of the present invention, wherein information is recorded and reproduced for the first and second tracks, wherein the first track is a groove. The second track is formed in a land shape between adjacent first tracks, and the first and second tracks record an address signal as address information, and the address signal of the first track. The recording is performed in the opposite polarity to the address signal of the second track, so that the address signals of tracks adjacent to the first and second tracks are not overlapped in the radial direction.

The information recording and reproducing apparatus according to the fifth aspect of the present invention is adapted to provide information to the first and second tracks of an optical disc having a spiral-shaped first track and a spiral-shaped second track on the same recording surface. An optical information recording and reproducing apparatus for recording and reproducing, comprising: an optical head for irradiating a laser beam to the track to record and reproduce a signal, and track designation means for selecting a corresponding track for recording and reproducing information to the first or second track; Focus means for focusing the light beam from the optical head on a predetermined track, tracking means for selectively tracking the first and second tracks by tracking the track, and moving the optical head for searching for a track; Track retrieval means, signal reproducing means for amplifying a reproduced signal reproduced by the optical head, and address reproducing number for reading the address signals of the first and second tracks. And data recording and reproducing control means for selecting a first or second track from the output of the address reproducing means and performing recording and reproducing of information on the track or sector based on the output of the track designating means; And information recording and reproducing means for recording and reproducing the information on the corresponding track or the sector of the recording surface by the output of the data recording and reproducing control means, and recording and reproducing the information on the first and second tracks. do.

In the information recording and reproducing apparatus according to the sixth aspect of the present invention, in the invention according to the eleventh aspect, the track designation means tracks to the first and second tracks by inverting the polarity of the tracking difference signal with respect to the optical head. It characterized in that for switching.

In the information recording and reproducing apparatus according to the seventh aspect of the present invention, in the invention according to the eleventh aspect, the address reproducing means compares the output of the track designation means with the track identification signal of the address reproducing means, It is characterized by outputting only a reproduction address signal corresponding to a track matching the output.

According to the configuration according to the first aspect of the present invention, information is recorded on the first track of the spiral shape and the groove shape and the second track of the spiral shape and the land shape by different modulation methods.

According to the configuration according to the second aspect of the present invention, the address signal is recorded in the same modulation scheme and the opposite polarity in the spiral-shaped groove-shaped first track and the spiral-shaped land-shaped second track.

According to the configuration according to the third aspect of the present invention, in a track in which a spiral-shaped groove-shaped first track and a spiral-land second track are adjacent, an address signal recorded with address information for identifying the track is provided. It is recorded so as not to overlap each other in the radial direction.

According to the configuration according to the fourth aspect of the present invention, in a track in which a spiral-shaped groove-shaped first track and a spiral-shaped second track are adjacent to each other, address signals as address information are opposite polarities in a radial direction. It is recorded so as not to overlap.

According to the configuration according to the fifth aspect of the present invention, when recording information, the track designation means selects a land home selection signal in response to the corresponding track selected from the first or second track based on a recording command sent from the host computer. And the tracking means applies an output based on the detection signal detected from the optical head to the optical head based on the land groove selection signal, drives the track search means to move the optical head, By tracking to the track, the focusing means focuses the light beam of the optical head on the track.

The data recording and reproducing control means controls the information recording and reproducing means to record information in the corresponding sector of the corresponding track selected on the basis of the output of the track designation means and the output of the address reproducing means. The information recording and reproducing means controlled by the data recording and reproducing control means applies a signal modulated by the encoded recording information to the optical head and modulates the optical head based on the recording information in the corresponding sector of the corresponding track of the optical disc. Record the signal.

When the information is reproduced, the track designation means outputs a land home selection signal in response to the corresponding track selected from the first or second tracks based on a read command sent from the host computer, and based on the land home selection signal, The tracking means applies the output based on the detection signal detected from the optical head to the optical head, drives the track search means to use the optical head, and tracks the light beam to the corresponding track, so that the focus means is a light beam of the optical head. To the track.

The data recording and reproducing control means controls the information recording and reproducing means so as to reproduce information from the corresponding sector of the track selected based on the output of the track designation means and the output of the address reproducing means. The information recording and reproducing means controlled by the data recording and reproducing means demodulates and reproduces the information detected by the optical head from the corresponding sector of the corresponding track of the optical disc.

According to the configuration of the invention according to the sixth aspect of the present invention, when recording and reproducing information on an optical disc, the track designation means inverts the polarity of the tracking error signal obtained from the optical head and outputs it to the optical head. Control tracking to two tracks.

According to the configuration according to the thirteenth aspect of the present invention, when recording and reproducing information on an optical disc, the address reproducing means compares the output of the track designation means with the track identification signal of the address reproducing means, and outputs and tracks of the track designation means. When the corresponding track identified by the identification signal is matched, a reproduction address signal corresponding to the track is output.

The optical information recording and reproducing apparatus according to the embodiment of the present invention will be described below with reference to the drawings.

1 is a diagram illustrating a sector format configuration of a land-home recording optical disc according to the first embodiment of the present invention. In FIG. 1, (a) shows the sector format of the home recording track as the first track, and the sector 13 is the sector ID portion of the sector ID section in which the address signals A1 and A2 of the sector are modulated and recorded. And a data field DF for recording data in a second modulation method, a gap G1 for not recording signals, and a buffer area B1 for absorbing disk rotational variations and various time variations. The data field DF consists of a synchronous clock area VFO 14 for clock in, a data mark SYN 15 indicating the start of data, user data, and an error correcting code 16.

FIG. 1 (b) shows the sector format of the land recording track as the second track, and the sector 17 is the sector ID part which recorded the address signals a1, a2 and a3 of the sector by the second modulation method, and the second data. It consists of a data field DF, a gap G2 and a buffer area B2 to be recorded by the modulation method.

The data field DF has the same configuration as that in FIG. In FIG. 1, the first modulation method is PE (Phase Encoding) modulation, which is one of the digital modulation methods, and the second modulation method is one of the digital modulation methods (2, for example). 7) Run Length Limited (RLL) modulation is used. Since the DR (Density Ratio) of the modulation method is 1: 3 and the PLL (Phase Lock Loop) circuit is required for reproducing the RLL signal, ID1 writes the address signal twice and ID2 writes three times. The lengths of the sectors 13 and 17 are set equal.

As described above, the ID1 and ID2 of the sectors 13 and 17 are aligned in the disk radius direction, and crosstalk of about -15 dB is generated in the ID portion, but the ID1 and ID2 modulation methods are different, and the ID1 signal reproduction circuit Since the demodulation scheme is different from that of the ID2 signal reproducing circuit, each ID signal can be reproduced normally without being affected by crosstalk.

In FIG. 1, only the ID portion of the home recording track and the land recording track are different modulation schemes, but the ID portion and the data portion may be different modulation schemes, and at least the ID portion and the ID portion of the ID portion and the data portion have different modulation schemes. You can expect.

2 is a sector format configuration diagram of the land-home recording optical disc of the second embodiment of the present invention.

In Fig. 2, the same numbers as in Fig. 1 indicate blocks having the same function. In Fig. 2, ID3 and ID4 are sector identification units in which address information is recorded.

The sector format of the home recording track shown in FIG. 2 (a) is the same sector format as the land recording format of FIG. 2 (b).

The sector identification parts ID3 and ID4 are modulated by the same modulation method, and the signal polarities are recorded opposite to each other.

That is, as shown in FIG. 2 (a '), ID3 records 1 of the channel bits of the modulation signal at the level of the land portion, 0 is recorded as the level of the groove portion, and ID4 of FIG. 2 (b'). 1 is recorded at the level of the groove portion and 0 is recorded at the level of the land portion.

As described above, the ID3 and ID4 of the sectors 13 and 17 are aligned in the radial direction of the disk, and crosstalk of about -15 dB is generated in the ID portion. Can only read the ID signal that has undergone signal inversion processing corresponding to the track, and can reproduce each ID signal normally without being affected by crosstalk.

3 is a sector format configuration diagram of the land-home recording optical disc in the third embodiment of the present invention.

In FIG. 3, (a) is a track format of a home recording track, and the track 18 is divided into a plurality of sectors 19. As shown in FIG. FIG. 3 (b) shows the track format of the land recording track, and the track 20 is divided into a plurality of sectors 21.

3 (c) shows the sector ID and the field ID format of the sectors 19 and 21, the VFO2 for clock synchronization, the address mark AM indicating the head of the address information, the track address TA, and the sector address. SA, the land home identification signal 22, the error detection signal CRC, and the postamp PA. In FIG. 3, the head sector 19 of the home recording track 18 and the head sector 21 of the land recording track 20 are shifted from each other by the distance G3, and the IDs of the sectors are in the track direction. Are arranged not to overlap along. In addition, the land home identification signal 22 of the sector indicates whether the corresponding ID is that of the home recording track 18 or the land recording track 20. For example, if the ID of the home recording track 18 is used. , 0, 1 is recorded if the land recording track 20 is used.

As described above, since the IDs of the tracks 18 and 20 are aligned in the disc radius direction by G3, they are not affected by crosstalk. In addition, even when there is cross talk, the ID signal reproducing circuit checks the land groove identification signal, whereby the ID signal of the track tracked by the light beam can be reproduced normally.

In addition, since the ID signal is shifted in the track direction, the effect that the pits of the ID portion are easily formed also occurs.

4 is a layout diagram of signals of the land-home recording optical disc in the fourth embodiment of the present invention.

In FIG. 4, (a) shows the configuration of the address signal of each sector in this embodiment, which is the same as that in FIG. FIG. 4B shows the relationship between the recording positions of the pit of the two VFO parts at the head of the address signal ID of the home recording track 23 and the land recording track 24. FIG. The recording pit 25 of the channel bit 1 of the address signal of the home recording track 23 is formed at the level of the land portion 28, and 0 is formed corresponding to the level of the groove portion 29. The recording bit 26 of the address signal is formed so that channel bit 1 corresponds to the level of the groove portion 29 and 0 corresponds to the level of the land portion 28. These pit 25 and pit 26 may be similarly formed also in 1st Example and 3rd Example. In this embodiment, the pit 25 and the pit 26 are recorded in a checkered state in which phases are shifted by half of the highest frequency period T of the address signal.

As described above, since the recording feet of the address signals of the tracks 23 and 24 are aligned with the position shifted by T / 2 in the disc radial direction, the influence of crosstalk can be greatly suppressed. Further, even if the address signal is reproduced by crosstalk, the land home identification signal 22 is checked, whereby the ID signal of the track tracked by the light beam can be reproduced normally.

In the first embodiment and the fourth embodiment, the address signal may be configured as the track address TA and the sector address SA, or may be constituted by the track identification signal 22, the address information AM, and the error detection signal CRC. The track address TA, the sector address SA, the track identification signal 22, the address information AM, and the error detection signal CRC may be configured.

Incidentally, in the optical disc described in the first to fourth embodiments, when the length of the home recording track is λ as the wavelength of the laser light and n is the refractive index of the disc substrate, λ / (8 N).

5 is a configuration diagram of an embodiment of an information recording and reproducing apparatus for recording and reproducing information on an optical disc of the present invention. In the following description, data is recorded as track designation means as CPU47, track search means as linear motor 34, signal reproduction means as head amplifier circuit 36, and address reproduction means as sector ID reproduction circuit 40. The reproducing control means will be described as the sector recording reproducing control circuit 41, and the information recording and reproducing means as the data modulation and demodulation circuit 42.

In FIG. 5, reference numeral 30 denotes an optical disc mounted and rotated on the motor 31, 32 denotes an optical disk 30 for recording, and 33 denotes an optical head for condensing laser light onto the recording surface 32. 34, linear motors LM as track search means for transporting the optical head 33 to search for the desired track, 35 are focus means for focus control of the light beam of the optical head 33, and tracking control and track. A focus tracking control circuit constituted by tracking means for retrace, 36 is a head amplifying circuit as signal reproducing means for amplifying and outputting a tracking error signal n and a reproduction signal C from the detection signal a of the optical head 33, (37 Is a binary circuit for binarizing the reproduction signal C, 38 is a laser driving circuit for driving a semiconductor laser of the optical head 33, 39 is a linear motor 34 for the purpose of the optical head 33; The linear motor control circuit 40, which controls to search for a track to be made, is an output of the binarization circuit 37. A sector ID reproducing circuit as the address reproducing means for outputting the sector address e and the land home identification signal q of the track of the sector ID from d, 41, the target sector address of the CPU data bus f for recording and reproducing the track sector address e and data. And a sector recording and reproducing control circuit as data recording and reproducing control means for generating a write gate signal g and a lead gate signal h to the corresponding sector, and 42 denotes the encoded data i (2-7) RLLC (Run Length). And a digital modulation demodulation circuit as information recording and reproducing means for digitally modulating and outputting the modulation signal j, and demodulating the binarized reproduction signal d to output the demodulation data k. 43 adds an error correction code to the recording data. An error correction circuit which generates one encoded data i and detects and corrects an error of the demodulated data k, 44 is a memory for temporarily storing data, and 45 is a host computer. , 46 is an interface IF, (47) is in the micro-computer CPU track designation means for controlling the entire information recording and reproducing apparatus to be connected by the host computer 45 and the SCSI (Small Computer System Interface) bus X. m is output from the CPU 47, is applied to the focus track control circuit 35 and the sector ID reproducing circuit 40, and the land groove for selecting recording reproduction to the land recording track or recording reproduction to the home recording track. Selection signal.

6 is a configuration diagram of the tracking control unit of the focus tracking control circuit 35 in FIG. In the figure, reference numeral 48 denotes a polarity inversion circuit of the tracking error signal n, 49 denotes a multiplexer MPX for selecting the tracking error signal n and its inverted signal n 'by the land home select signal m, and The tracking servo circuit P is an actuator drive signal for driving the tracking actuator of the optical head 33. By switching the land groove selection signal m, the polarity of the tracking error signal n is inverted to track the land or the home recording track.

FIG. 7 is a configuration diagram of the sector ID reproducing circuit 40 when the modulation signal system of the sector ID section of the land recording track and the home recording track is different in the optical disc shown in the first embodiment of FIG. 51A is an address reproducing circuit A for reproducing the sector ID of the home recording track, and 51B is an address reproducing circuit B. 52 for reproducing the sector ID of the land recording track. The multiplexer MPX selects each of the reproduction address outputs el and e2 of the address reproduction circuits 51A and 51B.

FIG. 8 is a configuration diagram of the sector ID reproducing circuit 40 in the case where the polarity of the modulation signal of the sector ID portion of the land recording track and the home recording track is reversed in the optical disc shown in the second embodiment of FIG. In the drawing, reference numeral 53 denotes an inversion circuit of the polarity of the binary reproduction signal d, 54 denotes a multiplexer MPX for selecting the binary reproduction signal d and its inversion signal d 'by the land home selection signal m, ( 55 is an address reproducing circuit, and q is a land home identification signal.

8 is arranged so that the positions of the IDs of the home recording track 18 and the land recording track 20 are not superimposed on the optical disc shown in the third embodiment of FIG. In the case of reproduction of the ID, the land home selection signal m is set such that the binarization signal d is selected by the multiplexer 54, so that land or home recording is combined with the land home identification signal q using FIG. Identifies the track.

9 is a detailed configuration diagram of the sector recording and reproducing control circuit 41, and is applied to the optical disc shown in FIG. 3 and FIG. In the figure, reference numeral 56 denotes a register for latching the destination address of the CPU data bus f in strobe S1, 57 denotes a comparison circuit A. 58 compares the output of the register 56 with the reproduction address e. The comparison circuit B. 59, which compares the identification signal q with the land home select signal m and outputs a match by the coincidence output of the compare circuit A 57, is transferred from the CPU data bus f to the register 60 at the strobe S2. The read write gate generation circuit outputs the latched read or write command to the data demodulation circuit 42 as the write gate g and the read gate h at the timing of the output of the comparison circuit B58.

The operation of the double-sided optical disc recording and reproducing apparatus for recording and reproducing information on the optical disc configured as described above will be described below.

The data recording operation will be described below.

The host computer 45 sends a recording command to the SCSI bus X, the CPU 47 interprets the recording command via the IF 46, and depending on whether the destination track is a land recording track or a home recording track, The land home select signal m is output, and the optical head 33 is focused on a predetermined recording track. As shown in FIG. 6, the focus track control circuit 35 inverts or reverses the signal polarity of the tracking error signal n from the optical head 33 in response to the land groove selection signal m. The signal P is applied to the tracking actuator coil of the optical head 33. Then, the linear motor drive circuit 39 issues a search command for the target track, drives the linear motor 34 to transfer the optical head 33 to the target track.

The recording data from the host computer 45 is once stored in the memory 44, and the error correction circuit 43 outputs the encoded data i to which the error correction code is added to the recording data.

The CPU 47 sets the recording sector address and the recording command in the sector recording / playback control circuit 41. The sector recording and reproducing control circuit 41 compares the recording sector address with the address output e of the ID reproducing circuit 40, and if a predetermined sector is detected by matching the addresses, the recording gate signal g becomes data. It is applied to the modulation / demodulation circuit 42. The recording gate g starts the data modulation / demodulation circuit 42, modulates the coded data i by (2-7) RRL, and applies the modulation signal j to the laser drive circuit 38.

The optical head 33 records the modulation signal j in the sector of the recording surface 32. The above data recording is repeated by the predetermined number of sectors.

The data reading will be described below.

When the host computer 45 sends a read command to the SCSI bus X, the CPU 47 interprets the command via the IF 46, and lands according to whether the destination track is a land recording track or a home recording track. The home select signal m is output, and the optical head 33 is focused and dragged to a predetermined recording track. As shown in FIG. 6, the forks track control circuit 35 drives the actuator by inverting or non-inverting the signal polarity of the tracking error signal n from the optical head 33 by the land groove selection signal m. The signal P is applied to the tracking actuator coil of the optical head 33. Then, the linear motor drive circuit 39 issues a seek command for the target track, drives the linear motor 34 to transfer the optical head 33 to the target track.

The CPU 47 sets the read sector address and the read command to the sector record reproduction control circuit 41. The sector record reproduction control circuit 41 compares the read sector address with the address output e of the ID reproduction circuit 40, and by matching the address, the sector record reproduction control circuit 41 selects a predetermined sector. Upon detection, the read gate signal h is applied to the data modulation / demodulation circuit 42.

The data modulation and demodulation circuit 42 is operated by the read gate h, and stores the reproduced data k reproduced by demodulating and detecting the detection signal d detected from the recording surface 32 by the optical head 33 in the memory 44.

The reproduction data stored in the memory 44 is subjected to error detection correction to the error correction circuit 43, respectively, and stored in the memory 44 again. The error corrected reproduction data is transmitted to the host computer 45 via the interface 46. The data reading operation is repeated by a predetermined number of sectors.

The operation of the ID reproducing circuit 40 and the sector recording and reproducing control circuit 41 will be described in detail below in contrast to the embodiment of the optical disc of the present invention to which it is applied.

As for the optical disc (Fig. 1) of the first embodiment, the configuration shown in Fig. 7 is applied to the ID reproducing circuit 40. Figs. In Fig. 1, the optical disc is recorded by modulating the ID portion of the land recording track and the home recording track by a different modulation method. Therefore, in Fig. 7, the binary reproduction signal d is simultaneously reproduced by the first address reproduction circuit 51A and the second address reproduction circuit 51B. When the modulation schemes of the address reproduction circuits 51A and 51B and the binary reproduction signal d match, the reproduction address signals e1 and e2 are outputted, and the corresponding reproduction address signals are made by the land home selection signal m. e1 and e2 are selected by the multiplexer 52 as a reproduction address signal e and output.

As to the optical disc (Fig. 2) of the second embodiment, the configuration shown in Fig. 8 is applied to the ID reproducing circuit 40, and the structure shown in Fig. 9 is applied to the sector recording and reproducing circuit 41. Figs. This applies.

In Fig. 2, the optical disc records opposite polarities of signal signals of the ID portion of the land recording track and the home recording track. In FIG. 8, the binarized reproduction signal d and the inverted reproduction signal d 'inverted by the inversion circuit 53 are selected by the land groove selection signal m in the multiplexer 54, and the address reproduction circuit 55 is selected. By demodulation. The address reproduction circuit outputs the reproduction address signal e and the land groove identification signal q to the sector recording and reproducing control device 41 in FIG.

In Fig. 9, the destination address of the CPU data bus f is latched in the register 56 in the strobe S1, and the comparison address 57 compares the destination address with the reproduction address signal e. The land home identification signal q is compared with the land home selection signal m. The write or read command of the CPU data bus f is latched in the register 60 at the strobe S2, and the write gate g or the read gate h is output by the AND operation with the comparison circuit 58 output. The write gate g and the read gate h are applied to the data modulation / demodulation circuit 42 to perform data modulation or data demodulation.

With respect to the optical disc (FIG. 3) of the third embodiment, the configuration shown in FIG. 8 is applied to the ID reproducing circuit 40, and the configuration shown in FIG. 9 is applied to the sector recording and reproducing circuit 41. FIG. Apply. In FIG. 3, in the optical disc, the address signal of the ID portion of the land recording track and the home recording track is recorded so that the ID portion does not overlap in the track direction. The reproduction of the address and the generation of the recording gate or the reading gate are the same as in the case of the optical disc of the second embodiment, except that the multiplexer 54 always selects the binary reproduction signal d in FIG. . As for the optical disc (FIG. 4) of the fourth embodiment, the configuration shown in FIG. 8 is applied to the ID reproducing circuit 40, and the sector recording and reproducing circuit 41 is shown in FIG. This applies. In FIG. 4, in the optical disc, the address signal of the land portion of the land recording track and the home recording track is recorded in a checkered state with bit positions alternately by T / 2 in the track direction. The reproduction of the address and the generation of the recording gate or the reading gate are the same as those applied to the optical disc of the second embodiment, except that the multiplexer 54 always selects the binary reproduction signal d in FIG.

According to the above structure, in land-home recording, the recording density on the optical disk is increased compared with the conventional one, and then the land adjacent to the conventional one is changed by changing the modulation method and the signal polarity or changing the ID position and the pit phase. The crosstalk between the recording track and the home recording track can be reduced, and data with little error or ID signal can be read without being influenced by the crosstalk.

In order to achieve the object of the present invention, the first to fourth embodiments of the above optical disk may be implemented in combination.

According to the configuration according to the first aspect of the present invention, since the information is recorded in the first track and the second track in a different modulation method, the recording density can be increased as compared with the conventional one, and between the first and second tracks. Crosstalk can be reduced, and errors in recording and reproducing of ID signals and data signals due to crosstalk between the first and second tracks can be prevented.

According to the configuration according to the second aspect of the present invention, since the address signals are recorded in the first track and the second track in the same modulation scheme and in the opposite polarity, the recording density can be increased and the first track can be increased. And crosstalk between the second tracks can be reduced, and errors in recording and reproducing of ID signals and data signals due to crosstalk between the first and second tracks can be prevented.

According to the configuration according to the third aspect of the present invention, since the address signals in which address information for identifying the tracks are recorded are recorded in adjacent tracks of the first track and the second track so as not to overlap each other in the radial direction. On the other hand, the recording density can be increased, and crosstalk between the first and second tracks can be reduced, and errors in recording and reproducing of ID and data signals due to crosstalk between the first and second tracks can be reduced. You can prevent it.

According to the configuration according to the fourth aspect of the present invention, since the address signals as the address information are written so as not to overlap each other in the radial direction on the track adjacent to the first track and the second track, the recording density is reduced. In addition, crosstalk between the first and second tracks can be reduced, and errors in recording and reproducing of ID signals and data signals due to crosstalk between the first and second tracks can be prevented.

According to the configuration according to the fifth aspect of the present invention, when recording and reproducing information on an optical disc, the track designation means polarizes the tracking error signal obtained from the optical head and outputs the optical head to the first and second tracks. By controlling the tracking of the optical disc, the recording density of the optical disc is increased compared with the conventional one, and the crosstalk between the first and second tracks is reduced, and the ID signal or data signal due to the crosstalk between the first and second tracks is reduced. The information can be recorded and reproduced so as to prevent errors in recording and reproducing.

According to the configuration according to the sixth aspect of the present invention, when recording and reproducing information on an optical disc, the address reproducing means compares the output of the track designation means with the track identification signal of the address reproducing means, and outputs and tracks of the track designation means. When the track identified by the identification signal is matched, the reproduction address signal corresponding to the track is outputted, so that the recording density of the optical disc is increased compared to the conventional one, and the crosstalk between the first and second tracks is increased. The information can be recorded and reproduced so that an error in recording and reproducing of the ID signal or data signal due to crosstalk between the first and second tracks can be prevented.

Claims (28)

An optical disc having a recording surface consisting of a first track of spiral shape and a second track of spiral shape, wherein information is recorded and reproduced on the first and second tracks, wherein the first track is formed in a groove shape, and the second track is formed on the second track. A track is formed in a land shape between the first tracks adjacent to each other, and the first and second tracks record information by different modulation schemes. An optical disc having a recording surface consisting of a first track of spiral shape and a second track of spiral shape, wherein information is recorded and reproduced on the first and second tracks, wherein the first track is formed in a groove shape, and the second track is formed on the second track. A track is formed in a land shape between the first tracks adjacent to each other, and the first and second tracks record at least an address signal among information by different modulation schemes. An optical disc having a recording surface consisting of a first track of spiral shape and a second track of spiral shape, wherein information is recorded and reproduced on the first and second tracks, wherein the first track is formed in a groove shape, and the second track is formed on the second track. The tracks are formed in a land shape between the first tracks adjacent to each other, and the first and second tracks record an address signal in which address information is recorded in the same coding scheme, and the address signal of the first track includes: And an polarity opposite to that of the address track of the second track. An optical disc having a recording surface consisting of a first track of spiral shape and a second track of spiral shape, wherein information is recorded and reproduced on the first and second tracks, wherein the first track is formed in a groove shape, and the second track is formed on the second track. A track is formed in a land shape between the first tracks adjacent to each other, and the first and second tracks record an address signal in which address information for identifying a corresponding track is recorded, and adjacent to the first and second tracks. And recording so that the address signals of the tracks do not overlap in the radial direction. An optical disc having a recording surface consisting of a first track of spiral shape and a second track of spiral shape, wherein information is recorded and reproduced on the first and second tracks, wherein the first track is formed in a groove shape, and the second track is formed on the second track. A track is formed in a land shape between the first tracks adjacent to each other, and the first and second tracks record an address signal which is address information, and the first track has a polarity opposite to that of the second track. And an address signal of the track and recorded so that address signals of tracks adjacent to the first and second tracks do not overlap in the radial direction. The optical disc according to claim 1, wherein when the wavelength of the laser light is λ and the refractive index of the disc substrate is n, the depth of the first track is λ / (8 · n). The optical disc according to claim 1, wherein the first and second tracks are divided into sectors which are recording and reproduction units of information, track addresses and sector addresses are recorded, and information is recorded and reproduced sector by sector in the sectors. 3. The optical disc of claim 2, wherein the address signals of the first and second tracks record track identification signals, address information, and error detection signals that identify the tracks. 4. The address track of claim 1, wherein the modulated channel bit 1 corresponds to the level of the land portion, and the channel bit 0 corresponds to the level of the groove portion as mark position recording of the address signals of the first and second tracks. And the address signal of the second track is recorded such that the modulated channel bit 1 corresponds to the level of the groove portion and the channel bit 0 corresponds to the level of the land portion. An optical disc having a recording surface consisting of a first track of spiral shape and a second track of spiral shape, wherein information is recorded and reproduced on the first and second tracks, wherein the first track is formed in a groove shape, and the second track is formed on the second track. Tracks are formed in a land shape between the first tracks adjacent to each other, and in the first track and the second track, the VFO signal of the clock synchronization of the address signal in which the address information is recorded is the same as that of the VFO signal between the adjacent tracks. An optical disc recorded by changing a phase by 1/2 wavelength of a frequency. An information recording and reproducing apparatus for recording and reproducing information on the first and second tracks of an optical disc having a spiral-shaped groove-shaped first track and a spiral-shaped second track on the same recording surface. An optical head for irradiating the track to record and reproduce a signal; Track designation means for selecting a corresponding track for recording and reproducing information on the first track or the second track; Focusing means for focusing the light beam from the optical head on a predetermined track; Tracking means for tracking the track and selectively tracking the first and second tracks; Track search means for moving the optical head to search for a track; Signal reproducing means for amplifying a reproduced signal reproduced by the optical head; Address reproducing means for reading address signals of the first and second tracks; Data recording and reproducing control means for selecting first and second tracks from the output of the address reproducing means and controlling recording and reproducing of information on the track or the sector based on the output of the track designating means; And information recording and reproducing means for recording and reproducing the information on the track or the sector of the recording surface by the output of the data recording and reproducing control means, and recording and reproducing the information on the first and second tracks. An information recording and reproducing apparatus. The information recording and reproducing apparatus according to claim 11, wherein the track designation means switches tracking to the first and second tracks by inverting the polarity of the optical tracking error signal with respect to the optical head. 12. The address reproducing means according to claim 11, characterized in that the address reproducing means compares the output of the track designation means with the track identification signal of the address reproducing means, and outputs only the reproduction address signal corresponding to the track matching the output of the track designation means. Information recording and reproducing apparatus. The optical disc according to claim 2, wherein when the wavelength of the laser light is λ and the refractive index of the disc substrate is n, the depth of the first track is λ / (8 · n). The optical disk according to claim 3, wherein the depth of the first track is? / (8 · n) when the wavelength of the laser light is? And the refractive index of the disk substrate is n. The optical disk according to claim 4, wherein when the wavelength of the laser light is λ and the refractive index of the disc substrate is n, the depth of the first track is λ / (8 · n). The optical disk according to claim 5, wherein when the wavelength of the laser light is λ and the refractive index of the disc substrate is n, the depth of the first track is λ / (8 · n). The optical disc according to claim 2, wherein the first and second tracks are divided into sectors which are recording and reproduction units of information, track addresses and sector addresses are recorded, and information is recorded and reproduced sector by sector in the sectors. 4. The optical disc of claim 3, wherein the first and second tracks are divided into sectors which are recording and reproduction units of information, track addresses and sector addresses are recorded, and information is recorded and reproduced sector by sector in the sectors. The optical disc according to claim 4, wherein the first and second tracks are divided into sectors which are recording and reproduction units of information, track addresses and sector addresses are recorded, and information is recorded and reproduced sector by sector in the sectors. The optical disc according to claim 5, wherein the first and second tracks are divided into sectors which are recording and reproduction units of information, track addresses and sector addresses are recorded, and information is recorded and reproduced by sectors in the sectors. 4. The optical disc of claim 3, wherein the address signals of the first and second tracks record track identification signals, address information, and error detection signals that identify the tracks. 5. The optical disc of claim 4, wherein the address signals of the first and second tracks record track identification signals, address information, and error detection signals that identify the tracks. 6. The optical disc of claim 5, wherein the address signals of the first and second tracks record track identification signals, address information, and error detection signals that identify the tracks. 8. The optical disc of claim 7, wherein the address signals of the first and second tracks record track identification signals, address information, and error detection signals that identify the tracks. The address signal of the first track is characterized in that the modulated channel bit 1 corresponds to the level of the land portion, and the channel bit 0 corresponds to the level of the groove portion. And the address signal of the second track is recorded such that the modulated channel bit 1 corresponds to the level of the groove portion and the channel bit 0 corresponds to the level of the land portion. 6. The address track of claim 1, wherein the modulated channel bit 1 corresponds to the level of the land portion, and the channel bit 0 corresponds to the level of the groove portion as mark position recording of the address signals of the first and second tracks. The address signal of the second track is recorded so that the modulated channel bit 1 corresponds to the level of the groove portion and the channel bit 0 corresponds to the level of the land portion. The address signal of the first track, wherein the modulated channel bit 1 corresponds to the level of the land portion, and the channel bit 0 corresponds to the level of the groove portion, as mark position recording of the address signals of the first and second tracks. And the address signal of the second track is recorded so that the modulated channel bit 1 corresponds to the level of the groove portion and the channel bit 0 corresponds to the level of the land portion.