KR100195555B1 - Recording and reproducing apparatus - Google Patents

Abstract

According to the present invention, a predetermined number of bits of control data are recorded in advance on the recording track of the recording medium in the form of a burst type change in the width of the recording track to control recording and resumption based on the control data.

Description

Recorder and playback device

1 is a schematic diagram showing the data format of a compact disc (CD).

2 is a schematic diagram showing a data format of a CD-ROM.

3 is a schematic plan view showing an optical disc as a recording medium according to the first embodiment of the present invention, and an enlarged view of three radial tracks on the optical disc.

FIG. 4 is a schematic diagram showing an optical pickup device employed to record data on the optical disc shown in FIG.

5 is a schematic diagram showing a data recording state on a recording track of an optical disc.

6 is a block diagram showing an arrangement of a recording / reproducing apparatus using the optical disc of the first embodiment as a recording medium.

7 is a schematic plan view of an optical disc as a recording medium according to a second embodiment of the present invention.

Fig. 8 is a block diagram showing a recording / reproducing apparatus using the optical disc of the second embodiment as a recording medium.

9 is a waveform diagram illustrating the operation of the recording / reproducing apparatus.

* Explanation of symbols for main parts of the drawings

1: optical disc 2: spare groove

4 Address area 11, 12, 13 Adder

110: recording circuit 112: encoder

120: regeneration circuit

The present invention relates to a recording medium that can be used in a data storage system, and to a recording device and a reproducing device using the recording medium.

There are various types of apparatus for recording and reproducing data on a recording medium, operating with various recording / reproducing principles, or using a recording medium having various appearances.

In general, data recording media may be classified according to an operating principle such as the magnetic and / or optical recording / reproducing principle, or may be classified according to their appearance, such as a tape type, a card type, or a disc type recording medium.

For example, there is a disc player for exclusive use such as a CD player that plays back a so-called compact disc (CD) in which audio signals such as voice or music are recorded in digital form in advance.

In the compact disc (CD) as shown in FIG. 1, a data format having 98 frames as one subcode block is standardized, and each frame is a 1-symbol / 8-bit signal (1--1). given as 8 to 14 modulation data, converting symbol / 8-bit signals into one symbol of the subcode, that is, 14 bits (L channel bits) of data consisting of one symbol of 14 bits. A 24-bit sync signal, 32 symbol data consisting of two sets of play date 12 symbols and 4 symbols of parity bits, each symbol consisting of 14 × 32 bits, and 3 merge bits installed between neighboring symbols. (merging bit). So each frame contains a total of 588 bits. The absolute address of each subcode block is given by the Q channel signal of the subcode and data such as music data is processed in one subcode block interval.

In the CD-ROM as shown in FIG. 2, the digital audio signals of the left and right channels recorded on the compact disc (CD) are alternately connected at intervals of one word (2 symbols = 16 bits) to make one channel. Is treated as serial data, and the CD is treated as a data storage device, and in the data format of the CD, 2K bytes of data are added by adding a header portion and a synchronization signal preceding each subcode block or 98-frame data. Configure each sector or block.

Since conventional CD players are dedicated to playback, data storage media such as write once compact discs (CD-WOs) or erasable compact discs (erasable-CDs), and The development of recording and / or reproducing systems using data storage media has been promoted. The CD-WO or erasable-CD uses a magneto-optical disk, the disk being formed of a rewritable magneto-optical recording medium, compatible with CD or erasable-CD, filed September 28, 1987 And co-pending in US Application No. 102,009.

In a data recording / reproducing system using a recording medium such as a CD-WO or an erasable-CD, it is necessary to efficiently control data on a block-by-block basis. However, in the CD data format, since there is only a small number of address data, it is difficult to control the data on a block basis when using the data format in a data recording medium such as a CD-WO or an erasable-CD.

It is a first object of the present invention to provide a data recording / reproducing system in which data is efficiently controlled on a block basis.

Another object of the present invention is to provide a recording medium capable of efficiently controlling data on a block basis.

Still another object of the present invention is to provide a recording medium capable of maintaining compatibility with a CD or a CD-ROM.

It is still another object of the present invention to provide a recording apparatus and a reproducing apparatus capable of efficiently controlling data on a block-by-block basis.

Another object of the present invention is to cope with the case of recording in continuous recording mode, such as when recording music data or when recording CD-ROM recording data, and when using a device such as CD-WO or erasable-CD As described above, it is to provide a data recording apparatus that can use an address on a disc in an intermittent recording mode to provide fast access of recording / reproducing data for each sector.

The above and other objects of the present invention are achieved by a recording medium having a recording track whose recording track width varies in a burst-like manner to represent control data of a predetermined number of bits. The control data is address data for each data block in one unit. The area containing the track widthwise change and thus the address data represents a data recording area or a data non-recording area depending on the recording mode, in which the recorded data is convolutionally encoded. encoding mode or sector completion encoding mode.

In another embodiment of the present invention, the recording medium has a recording track in which the centerline of the recording track is periodically displaced with respect to the track width in relation to the virtual centerline of the recording track. The track width also changes in a burst shape, in which period data is pre-recorded by the deviation of the track centerline with respect to the track width, and control data of a predetermined number of bits is indicated by the burst type change in the track width. do.

The present invention includes an apparatus for recording data on such a recording medium, the apparatus for detecting a control data signal recorded on the recording track and having two pairs of detectors each of which has a track width Detection means arranged across and generating a separate push-pull output, and control means for controlling a data recording operation on a recording track based on the control data. The control data is addressless data and the control means controls the recording on the recording track based on the reproduced address signal. When the recording medium has the recording track in which the centerline of the recording track is periodically displaced with respect to the track width in relation to the virtual centerline of the recording track, the detecting means detects the periodic data and the control data, and The control means controls the recording operation on the recording track based on the control data and the period data indicated by the push-pull output of the detection means.

The above and other objects of the present invention will become more apparent by understanding the following techniques with reference to the accompanying drawings.

With reference to the drawings, exemplary embodiments of the present invention will be described in more detail.

Referring to FIG. 3, which schematically shows the whole or a part of the optical disk as a recording medium according to the first embodiment of the present invention, a transparent base plate having a vertically magnetized film having magneto-optical effects ( The optical disc 1 formed on the base plate is used as a magneto optical disc. A land provided between the spirally formed pregrooves 2 is formed as the recording track 3, and the block data completed by 2K bytes of data according to the CD-ROM data format mentioned above is recorded in the recording track. Record on (3) magneto-optically. The long portion of the length of the helical track 3 constitutes a data area 6 in which data is recorded.

In the recording track 3, an address area 4 is located at an equidistant position along the length of the track 3 corresponding to a sync signal (SYNC) portion or an error correction code (ECC) portion in the CD-ROM data format. Is provided. In each address area 4 a burst-like change appears across the track width, for example. 19-bit address data is preliminarily recorded in each address area 4. The signal spectrum of the address data generated by the change across the track width is selected to display a component higher than that of the frequency spectrum of the servo region.

A lead-in area 7 is formed in the radially inner area from the data area 6, where lead-in data indicating the recording state of the data area 6 is recorded.

In the optical disc 1 of the first embodiment of the present invention, address data of a predetermined number of bits is recorded in each address area 4 by the change in the both ends of the track width. As shown in Fig. 4, a four-segment detector 10 composed of four light detectors A, B, C and D is used as an optical pickup for reading data in association with a laser light source (not shown). therefore. Data in the form of an add output signal S _A + S _B + S _C + S _D obtained by adding the outputs S _A , S _B , S _C and S _D of the respective detectors A, B, C and D in the adder 11 The signal RF can be detected. On the other hand, the detector A and the output of B S _A and an addition output produced by adding the S _B from the adder (12) (S _A + S _B) to the output S _C and S _D of the detector C, and D adder (13 from Address information signal ADR in the form of a subtracted output signal such as (S _A + S _B )-(S _C + S _D ) obtained by subtracting the subtracted output (S _C + S _D ) generated by the subtractor 14 Can be detected, and the detectors A, B, and C, D are arranged in the longitudinal direction or the XX 'direction of the recording track 3, that is, the push-pull outputs S _A -S _D and S _B -S _And the detectors A, D, and B, C are arranged in the transverse direction of the recording track 3, that is, in the YY 'direction.

The address information ADR does not substantially affect the data signal RF. Thus, as shown in FIG. 5, the data recording area 5 can be extended to the address area 4 of the recording track 3.

In the above-mentioned optical disc 1, the address area 4 is provided at predetermined intervals along the length of the recording track 3, and the address information of the signal spectrum beyond the servo area is changed as a change across the track width. By displaying, block data made up of 2K bytes of data in accordance with the CD-ROM data format based on the address information can be recorded on the recording track 3 or can be reproduced from the track and recorded on the recording track 3. Tracking servos or focusing servos are not disturbed by the address information or data.

Data recording on the optical disc 1 can be carried out in two modes. One of the modes is the continuous recording mode described above. The continuous recording mode is convenient for direct recording of CD-ROM data or continuous data, such as music data.

In the continuous recording mode, since there is no time period lacking data, as shown in FIG. 5, a pit 5 is also formed in the address area 4, which is used as the data recording area at the same time. do.

Another mode is the mode for intermittent recording, which is convenient for recording data at an arbitrarily selected address as in the case of a CD-WO or erasable-CD case.

The basic data configuration of the intermittent recording mode is similar to that of the continuous recording mode, except that a 12-byte sync signal that blocks music signals in the format shown in FIG. 2 is not provided in the intermittent recording mode. In the mode, data is recorded in 98 frame sectors as one recording unit. In each of these sectors, the same data as the data of the data format shown in FIG. 2 except for the 12-byte sync signal for blocking the music signal is recorded.

Thus, in the intermittent recording mode, a vacant region corresponding to 12 bytes may be in each sector having a data capacity of 2352 bytes in total. The 12-byte free area corresponds to the address area 4.

Therefore, when data is recorded in the intermittent recording mode, no data is recorded in the address area 4, so that address data recorded in the address area remains after data writing. Therefore, the address information recorded in the address area 4 can be sorted again to find the desired sector.

In the intermittent recording mode, the completed encoding in each sector is used instead of convolutional encoding. Encoding completion in each sector can be realized by the method described in 1988 Japanese Patent Application No. 118567. The merging bit when writing in accordance with EFM modulation is reset in each sector.

6 schematically shows a digital data recording / reproducing apparatus applied to the present invention. The apparatus is designed to optically record or reproduce digital data using the optical disc 1 shown in FIG. 3 as a recording medium, and to include a recording circuit 110 and a reproduction circuit 120. As shown in FIG.

The optical disc 1 has the above-mentioned address area 4 in which physical address data is recorded in each of the areas according to the burst type change in the track width. The disk 1 rotates at a constant linear velocity (CLV).

The write circuit 110 may select a signal from the terminal 114 and set the continuous write mode and the intermittent mode.

In the continuous recording mode, 12 bytes of synchronization signals are provided to each sector, but not in the intermittent recording mode.

During recording, data to be recorded on the optical disc 1 is supplied from the data input terminal 111 to the encoder 112 of the recording circuit 110. The address of the optical disc 1 can be obtained from the address information recorded in the address information section 4 so that a desired address can be found in the address information section for data recording. Data is generated from the data input terminal 111 into a predetermined frame structure in the encoder 112 to add a duplex error correction code of C1 and C2 series. The encoding is performed by convolutional encoding for continuous recording mode and sector-complete encoding for intermittent recording mode. The data to which the duplex error correction code is added at the encoder 112 is modulated 8 to 14 in the EFM circuit 113 to be recorded in the sector of the optical disc 1 having the desired address.

In the continuous recording mode, data is recorded in the address area 4 provided on the optical disc 1. Conversely, in the intermittent recording mode, no data is recorded in the address area 4 of the optical disc 1, so that address data recorded in the address area 4 is not affected by the burst type change in the track width. .

The data recorded on the disc 1 can be reproduced by the inverse sequence of the sequence adopted for recording.

Therefore, the above-described continuous recording mode or intermittent recording mode can be set in the reproduction circuit 120 in accordance with the selection signal from the terminal 124.

The data reproduced from the disc 1 is demodulated 8 to 14 in the EFM demodulation circuit 121 of the reproduction circuit 120 before being supplied to the decoder 122. In accordance with the selection signal from the terminal 124, the decoder 122 switches between decoding processing corresponding to convolutional encoding for the continuous recording mode and decoding processing corresponding to sector completion encoding for the intermittent recording mode. The decoded output is transmitted to the output terminal 123 as reproduced data.

When searching for a desired sector during reproduction, the information of the Q-channel of the subcode can be used in the continuous recording mode. If the frequency spectrum of the address data recorded in the address area 4 of the disc 1 and the frequency spectrum of the data recorded by the pit or tracking signal are designed to be separated from each other according to the burst type change form of the track width Even if the recording mode is a continuous recording mode, the address data recorded in the address area 4 can be used to find a desired sector.

In the intermittent recording mode, since the address information of the address area 4 of the optical disc 1 remains, the address data recorded in the address area 4 can be used to find a desired address.

In the above-described optical disc of the present invention, an address area of a predetermined length is provided in a predetermined space along the track length, and physical address data is recorded in the address area in the form of a change in track width, and recorded in the address area. The address data thus obtained can be used for recording the data in the previously determined sector.

Since the address data in the address area is not recorded as a pit, it is possible to record data in the address area when recording the record data in the continuous recording mode, as in recording music data or CD-ROM data.

In the intermittent recording mode for CD-WO or erasable-CD, a 12-byte sync pattern representing an empty area can be recorded in the address area 4. In this case, since the address data recorded in the address area 4 remains, the address data of the address area 4 can be used to access at high speed when searching for a desired sector.

Therefore, according to the present invention, the address data on the disc can be used when using the apparatus of the present invention as a CD-WO or an erasable-CD, and at the same time compatibility with the CD-ROM is maintained.

Referring to FIG. 7, which shows an optical disc as a recording medium according to the second embodiment of the present invention, the optical disc 21 records lands formed spirally between pregrooves 22. ) As. The center line l ₁ of the recording track is shifted at a predetermined period in the track width direction or the YY 'direction with respect to the virtual center line l ₀ . The width of the recording track 23 is changed in a burst type manner. Similarly to the optical disc 1 of the first embodiment described above, 2K bytes of complete block data conforming to the above-described CD-ROM data format are magneto-optically recorded on the track 23.

In the optical disc 21 in the second embodiment of the present invention, the recording track 23 is in the form of a sine wave to provide predetermined periodic data WCK corresponding to a sampling frequency of 22.05 kHz, wherein the frequency is CD. Half the sampling frequency of the ROM is 44.1kHz. In addition, an address area 24 is formed at predetermined intervals, which are recorded together with a synchronization signal SYNC or an error qualitative signal ECC according to the CD-ROM data format, and the address area 24 is burst-shaped across the track width. It is formed in accordance with the track change. For example, 19 bits of address data are recorded in advance by the track change in the horizontal direction. The signal spectrum of the address data formed by the track width direction change is selected to be higher than the signal spectrum of the servo region.

A lead-in area 27 in which lead-in data indicating a recording state of the data area 26 is recorded is formed inside the radioactive area of the data area 26 of the optical disc 21.

In the second embodiment of the present invention, the data signal RF can be detected as the add output signal S _A + S _B + S _C + S _D from the adder 11, while the period information WCK and address data ADR are shown in FIG. As in the case of the first embodiment of the invention, it can be detected as a subtracted output signal (S _A + S _B )-(S _C + S _D ) from the subtractor 14 by using the quadrant detector 10 shown in FIG. Can be.

The block diagram of FIG. 8 shows the arrangement of a recording / reproducing apparatus using the optical disc 21 shown in FIG. 7 as a recording medium.

The recording / reproducing apparatus is formatted according to the CD-ROM data format described above by the recording track 23 of the optical disc 21 while the disk 21 is rotated at a constant linear speed by the spindle motor 30. It is designed to be optically scanned by the optical pickup 31 for the recorded / reproduced data.

The optical pickup 31 mainly comprises a laser diode (not shown) for outputting a laser beam for data recording / reproducing, an optical sensor for optically detecting data in the form of light reflected from a recording track of the optical disc 21, and a laser. It consists of an optical system (not shown) which irradiates the optical disk 21 with a laser beam from the diode and sends the beam reflected back from the disk 21 to the light sensor. The optical pickup 31 comprises two quad split photo detectors 32 and 33 as light detectors, and (by means not shown) the P-polarized component in the optical system reflects the laser beam reflected from the disk 21. And separated into S polarized light components and then transmitted to the four split photodetectors 32,33.

Regarding the detection output from the four-segment photodetector 32 that receives the P polarization component of the reflected beam, it is arranged in the longitudinal direction (X-X 'direction) of the recording track 23 of the disk 21. the outputs S _a and S _B of the detectors a and B are supplied to the adder 34, and at the same time the detector output of the C and D S _C and S _D are supplied to the adder 35.

The adder output signal S _A + S _B from the adder 34 is supplied to adders 36 and 37, and at the same time the adder output signal S _C + S _D from the adder 35 is added to the adder 36. And 41).

Regarding the detection output from the four-segment photodetector 33 receiving the S-polarized component of the reflected beam, it is arranged in the longitudinal direction (X-X 'direction) of the recording track 23 of the disk 21. The outputs S _A ′ and S _B ′ of the detectors A ′ and B ′ are supplied to the adder 38, while the outputs S _C ′ and S _D ′ of the detectors C ′ and D ′ are supplied to the adder 39.

Adder output signal S _A ′ + S _B ′ from adder 38 is supplied to adders 37 and 40 and at the same time add output signal S _C ′ + S _D ′ from adder 39. Is fed to adders 40 and 41.

An addition output signal S _A + S _B + S _C + S _D by the adder 36 and an add output signal S _A '+ S _B ' + S _C '+ S _D ' by the adder 40 Is supplied to the subtractor 42, so that the RF signal or RFS reproduced from the subtractor 42, i.e.

RFS = (S _A + S _B + S _C + S _D )-(S _A '+ S _B ' + S _C '+ S _D ')

Is generated as a subtracted output signal.

The reproduced RF signal or RFS is supplied to a reproduction block 43, in which a magnet is formed in accordance with the above-mentioned CD-ROM data format and magnetized on the recording track 23 of the optical disc 21. A reproduction operation of 2K bytes of completed block data recorded as a rule is performed under the control of the system controller 100 to reproduce block data from the reproduced RF signal RFS.

On the other hand, an addition output signal S _A + S _B + S _C '+ S _D ' from the adder 37 and an addition output signal S _C + S _D + S _C '+ S from the adder 41. _D ') is supplied to the subtractor 44, from which the subtracted output signal RFC, i.e.

RFC = (S _A + S _B + S _A '+ S _B ')-(S _C + S _D + S _C '+ S _D ')

Is generated and supplied to the control block 50.

At the input stage of the control block 50, to separate the reproduced control signal RFC from the sine signal component of 22.05 kHz supplied from the recording track 22 of the disc 21 in the form of a sine wave. The output of the subtractor 44 is supplied to the band pass filter 51 using a tank circuit having a resonant frequency of 22.05 kHz and a high Q. The sinusoidal signal component corresponds to predetermined period information WCK. The output of the subtractor 44 also allows the high pass filter 52 to separate from the reproduced control signal RFC the address data component ADR previously recorded on the recording track 22 of the disc 21 in accordance with the change in the track width direction. Is supplied.

The sine wave signal (FIG. 9) corresponding to the predetermined period data WCK is separated by the band pass filter 51 and supplied to phase comparators 53 and 54, and at the same time the high pass filter 52 The address data component signal ADR separated from the control signal RFC at is supplied to the phase comparator 55 and the address decoder 56.

The phase comparator 53 performs a phase comparison between the sinusoidal signal obtained by the band pass filter 51 and the reference phase signal from the reference oscillator 57 for spindle servoing, and outputs the comparison output. The spindle servo system is configured to transmit the phase compensation circuit 58 to the drive circuit 59 of the spindle motor 30 to rotationally drive the optical disc 21 at a fixed line speed.

The phase comparator 54 performs a phase comparison between the output of the divider 61 which divides the oscillating output of the voltage controlled oscillator 60 by a factor of 196 and the above-mentioned sinusoidal signal obtained from the band pass filter 51. do. The comparison output is sent to the signal adder 63 through a low pass filter 62 and the output of the signal adder is supplied to the control input terminal of the voltage controlled oscillator 60. The circuits 54, 60, 61, 62 and 63 constitute a so-called phase locked loop (PLL) type clock reproduction system in which the oscillation phase of the voltage controlled oscillator 60 matches the phase of the sinusoidal signal. .

The phase comparator 55 performs a phase comparison between the oscillation output of the voltage controlled generator 60 and the signal of the address data component ADR generated at the output of the high pass filter 52, and the result of the comparison is low pass. The so-called PLL control system in which the oscillation phase of the voltage controlled oscillator 60 coincides with the bit clock phase of the address data ADR through the pass filter 64 and the switch 65 to the signal adder 63. Configure.

The switch 65 is initially closed and then controlled by the output of the phase comparator 54 of the clock regeneration system to open when the oscillating phase of the voltage controlled oscillator 60 is phase locked to the sinusoidal signal. . Favorably. The control is implemented such that the switch 65 is closed only during an address period after the bit clock phase of the address data ADR is correctly detected.

Under the PLL control by the comparison outputs of the phase comparators 54 and 55, the voltage controlled oscillator 60 outputs a system clock having a frequency of 4.3218 MHz that matches the bit clock phase of the address data ADR.

The system clock generated by the voltage controlled oscillator 60 is supplied to a system controller 100 employed to control the operation of the recording / reproducing apparatus, and at the same time the address decoder 56 and the recording data buffer memory 90 Is supplied.

According to the signal of the address data ADR generated by the high pass filter 52, the address decoder 56 decodes the address data ADR based on the system clock, and transmits the address data ADR to the system controller 100. do.

In the write mode, the system controller 100 controls the data buffer memory 90 having write data, and the data buffer when the control is performed for each data block as a unit based on the address data ADR. The write data from the memory 90 is sent to the write processor 91. The recording operation is controlled such that the block data to be completed in 2K bytes in accordance with the CD-ROM data format is magneto-optically recorded on the recording track 23 of the optical disc 21.

In the reproducing mode, the system controller 100 controls the data processing operation by the reproducing processing block 43 to reproduce the block data completed in 2K bytes, and at the same time, controls in units of blocks by using the address data ADR. Perform It is formed in accordance with the 2-byte complete block data CD-ROM data format, and is magneto-optically recorded on the recording track 23 of the optical disc 21.

In the recording medium of the present invention, the recording track width is changed in a burst manner at regular intervals along the track length so that the control data having a predetermined number of bits controls the recording data in block units using control data. It is recorded in advance by the change in both ends of the track width.

In the recording medium of the present invention, the track center line is periodically displaced across the track width with respect to the virtual track center line, and at the same time the track width is changed in a burst manner. In this manner, the period data is pre-recorded as data for control in units of blocks of recording data by shifting both ends of the track width of the track center line. At the same time, the control data having a predetermined number of bits is recorded in advance by the track width direction change so that block-based control of the recording data can be performed based on the period data and the control data.

According to the optical disc of the present invention, one subcode block is composed of a predetermined frame, and absolute address data can be pre-recorded as control data according to the change shape of the recording track width direction, so that absolute address data of one sub block is Can be obtained by reading one subblock in its entirety. Thus, data recorded or reproduced by the medium of the recording track can be controlled based on the address data, so that the data can be efficiently controlled for each block completed with 2K bytes. In addition, even when data of a CD or CD-ROM data format is recorded on a recording track, address data of a predetermined number of bits previously recorded as the width change of the recording track does not affect the data of the CD or CD-ROM format. Since the data in the CD or CD-ROM format can be maintained compatible with the CD or CD-ROM.

Further, according to the recording apparatus of the present invention, the recording operation is controlled by the control means based on the control data or the periodic data and the control data detected from the recording medium by the control means, so that the block of the recording data is controlled. Unit control can be performed simply and reliably.

Further, according to the reproduction apparatus of the present invention, the reproduction operation is controlled by the control means based on the periodic data or the control data and the control data detected from the recording medium by the detection means, so that the unit of block of the recording data is controlled. Can be controlled simply and reliably.

Although the invention has been shown and described in connection with the preferred embodiments, the invention may be embodied in various modifications and alterations by those skilled in the art without departing from the spirit and scope of the invention.

Claims (7)

An apparatus comprising the recording track whose width of the recording track changes along the recording track to indicate control information, wherein the recording medium is used for recording the recording data, wherein the control information and the recording data are detected. Detecting means having two pairs of detectors respectively disposed at both ends of the track width; And means for adding and subtracting an output signal from selected ones of the detectors to generate control signals indicative of the control information. The apparatus of claim 1, wherein the control signals represent address data. An apparatus using a recording medium having a recording track in which a width of a recording track varies along a recording track to indicate address data, wherein the recording medium is recorded on the recording track, wherein the address data and the recording data are detected. Detecting means having two pairs of detectors respectively disposed across the track width, and adding and subtracting an output signal from selected ones of the detectors to generate a control signal representing the address data. Means, wherein the record information is convolutionally encoded. A recording track having a centerline and a track width, wherein the centerline is periodically displaced with respect to the track width to represent periodic data, and the track width varies along the recording track to represent control data. A recording apparatus, comprising: at least two pairs of detectors for detecting the period data and the control data, the detector including at least two pairs of detectors disposed respectively across the track width, the output signal from a first detector in each of the detector pairs; And combining means for combining the output signals from the second detector in each of the detector pairs to generate push-pull output signals, wherein the push-pull output signals represent the output data and the control data. Way; And control means for controlling recording of the recording data on the recording track based on the period data and the control data appearing as the push-pull output signals. 5. The recording apparatus according to claim 4, wherein said detecting means includes means for adding said output signal from said first detector in each of said detector pairs to said output signal from said second detector in each of said detector pairs. . A reproducing apparatus using the recording medium having the recording track whose width of the recording track changes along the recording track to represent control data, the reproducing apparatus detecting the control data signals recorded on the recording track, the both ends of the track width Detecting means having at least two pairs of detectors each disposed in a combination, the push-pull output comprising a combination of an output signal from a first detector in each of the detector pairs and an output signal from a second detector in each of the detector pairs; Combining means for generating signals, said push-pull output signal representing said control data; And control means for controlling reproduction of data recorded on the recording track in response to the push-pull output signal. A recording track having a width varying in width of the recording track along the recording track to indicate control information, the recording track having areas with widthwise changes, wherein recording data is recorded in the areas; An apparatus using a medium, comprising: detecting means for detecting the control information and the recording data and having two pairs of detectors disposed respectively across the track width; And adding and subtracting means for adding and subtracting output signals from selected ones of the detectors to generate control signals indicative of the control information, wherein the control signals represent address data, and the write data are sector complete. Device encoded according to the sector complete type encoding algorithm.

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