JPH07254233A - Data recording method, data recording medium and data streamer - Google Patents

Abstract

PURPOSE:To record sub data in addition to main data and obtain a data streamer which is high in utilization factor of tracks. CONSTITUTION:When data are recorded on slant tracks on a magnetic tape 32 by rotary heads 31A and 31B, a sub-code, a synchronizing signal and a margin are added by a sub-code adding circuit 24, a synchronizing signal adding circuit 27 and a margin adding circuit 28 respectively to main data which are inputted through an interface controller 10. Each track is divided into a main data region and margin regions on both the edges of the main data region. The main data region of each track is divided into a plurality of blocks and the synchronizing signals, the sub-codes and the main data are recorded in the respective blocks.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data recording method, a data recording medium and a data streamer for recording data sent from a computer or the like on an inclined track on a magnetic tape by a rotary head.

[0002]

2. Description of the Related Art In a computer, in order to protect data written in a hard disk, for example,
These data are transferred and recorded once a day to a data recorder called a data streamer.

Conventionally, a normal analog audio tape recorder has been widely used as the data recorder. However, in this analog audio tape recorder, the consumption of the magnetic tape is extremely large and the data rate at the time of recording is low, so that it takes time to record and transfer the data. Further, the analog audio tape recorder has a drawback in that it does not perform high-speed search operation, and therefore it takes time to search for a desired data start portion, that is, so-called cueing.

Therefore, a helical scan type digital audio tape recorder using a rotary head, a so-called DA is used.
It is practiced to use T as a data recorder.

When DAT is used as a data recorder, the data from the host computer is converted into DAT format data before recording. DA
In the T format, as shown in FIG. 8, two heads having different azimuths are formed during one rotation.
One frame is composed of the tilted tracks T _A and T _B of the book, and 16-bit PCM audio data is interleaved and recorded with this one frame as a unit.
One track has 36 bytes as one block 19
It consists of 6 blocks. Of these, 34 blocks at both ends are sub-areas, and 128 blocks in the center are main areas.

The sub-area includes a margin section, a sub-code PLL preamble section, and a first section from one end of the track.
Subcode section, Postamble section, Gap section between adjacent blocks, Track King (ATF: Automatic Track
Finding) signal section, adjacent block gap section, data PLL preamble section, adjacent block gap section, ATF signal section, adjacent block gap section, subcode PLL preamble section, second subcode section, postamble section, It is divided into a gap section between adjacent blocks and a margin section. The first sub-code section and the second sub-code section are composed of 8 blocks, and the other sections are composed of a predetermined number of blocks.

The main area is composed of 128 data blocks. As shown in FIG. 9, in one data block, a sync signal, a PCM ID, a block address, and a parity are arranged in 1 byte from the beginning of the block,
Main data is located in the next 32-byte section.

When handling an audio signal, the main data is 16-bit PCM data for each of the L channel and the R channel. As shown in FIG. 10, the 16-bit main data is interleaved in the main area of one frame, that is, two tracks, and is arranged together with the parity Q. In this case, approximately 5760 bytes of data will be recorded in the main area of one frame.

As described above, in the DAT format, by dividing one track into a main area and a sub area, after-recording can be performed using the sub area.

Here, the structure of the error correction code of the main data in the DAT format is a two-dimensional code, as shown in FIG. 11, and the code plane is composed of four planes for one track, respectively in the C1 and C2 directions. It is encoded.

When the DAT is used as a data recorder, the data sent from the host computer is treated as 16-bit data and treated in the same manner as the PCM data. Record in the area. In that case, 2 bytes 16 bits of data corresponding to the L and R channels are used,
For example, the upper 4 bits are recorded as the format ID, and the lower 8 bits are recorded as the logical frame number. The format ID indicates a format unique to the data recorder, and logical frame numbers, for example, 23 frames are set as one unit, and frame numbers 1 to 23 are added to each unit.

As a data recorder format using such DAT, for example, ECMA (EU
DDS and DDS2 are defined by the RPPEAN COMPUTER MANUFACTURERS ASSOCIATION standard.

In the DDS format or the DDS2 format, as shown in, a physical tape start position (PBOT: PBOT: PBOT :) is provided in the head area following the leader tape as an area for loading and unloading the magnetic tape.
A device area from the Physical Beginning of Tape to a logical tape start position (LBOT: Logical Beginning of Tape) is defined, and a reference area and a system area are provided next to the device area. The reference area is used as a physical reference when recording a system log (history information) in the system area. Then, a data area for recording data is provided next to the system area, and E is provided next to this data area.
An OD (EOD: End of Data) area is provided.

Further, in the above DDS2 format,
Two partitions P1 each consisting of a reference area, a system area, a data area and an EOD area
A two-partition tape having P2 is defined, and a system log (history information) for each partition P1, P2 is recorded in the system area of the partition P1, P2.

[0015]

By the way, since the data recorder for recording computer data does not require the after-recording, the DDS format and the DDS2 format have a problem that the use efficiency of the track is low.

Therefore, the present invention has been made in view of the above-mentioned conventional circumstances, and has the following objects.

That is, an object of the present invention is a data recording method for recording data on a slanted track on a magnetic tape by a rotary head, in which a sub-code is also recorded together with main data, and data recording with high track utilization efficiency is achieved. To provide a method.

Another object of the present invention is a data recording method for recording data on a slanted track on a magnetic tape by a rotary head, in which a sub code is recorded together with main data, so that the track can be used efficiently. The purpose of the present invention is to provide a data recording method for recording a parity for detecting an error of a subcode.

Another object of the present invention is a data recording method for recording data on a slanted track on a magnetic tape by a rotary head, which records a sub-code together with main data, so that the track can be used efficiently. The purpose of the present invention is to provide a data recording method for recording a parity for detecting an error of a subcode.

Another object of the present invention is a data recording medium in which data is recorded on a tilted track on a magnetic tape by a rotary head, and a subcode is recorded together with main data, so that the track can be used efficiently. It is to provide a data recording medium.

Still another object of the present invention is a data streamer for recording data on a slanted track on a magnetic tape by a rotary head, which has a high track usage efficiency and is used for detecting a subcode error. It is to provide a data streamer that also records parity.

Another object of the present invention is a data streamer for recording data on a slanted track on a magnetic tape by a rotary head, which records a sub-code together with main data so that the track can be used efficiently and further. It is to provide a data streamer that also records the parity for error detection of subcodes.

Another object of the present invention is a data streamer for recording data on a slanted track on a magnetic tape by a rotary head, and performing tracking control without recording a special signal for tracking control. It is to provide a data streamer that can.

[0024]

SUMMARY OF THE INVENTION The present invention is a data recording method for recording data on a tilted track on a magnetic tape by a rotary head, wherein one track is a main data area and margin areas at both ends of the main data area. , The main data area of each track is divided into a plurality of blocks, one block is divided into a plurality of sections, the sync signal is recorded in the first section of each block, and the subcode is recorded in the second section. However, the main data is recorded in the third section.

In the data recording method according to the present invention, a fourth section is provided between the second section and the third section of each block, and a second section for detecting an error of the subcode recorded in the second section is provided.
It is characterized in that the header parity consisting of bytes is recorded in the fourth section.

A data recording method according to the present invention is characterized in that delimiter information indicating a delimiter of main data is recorded in the second section of each block as the subcode.

The data recording method according to the present invention is characterized in that the subcode is recorded in the second section of each block of the absolute position information of the recording unit of the main data.

The data recording method according to the present invention is characterized in that the discriminating information of each area on the magnetic tape defined by the tape format as the subcode is recorded in the second section of each block.

A data recording / recording medium according to the present invention is a magnetic tape in which data is recorded on a tilted track by a rotary head, and one track is a main data area and margin areas at both ends of the main data area. The main data area of each track is divided into a plurality of blocks, one block is divided into a plurality of sections, a sync signal is recorded in the first section of each block, and a subcode is recorded in the second section. It is characterized by comprising a magnetic tape in which main data is recorded in the third section.

Further, the present invention is a data streamer for recording data on a slanted track on a magnetic tape by a rotary head, and an interface controller for exchanging data with the outside, and input through the interface controller. Subcode generating means for generating a subcode to be added to the main data, subcode adding means for adding a subcode to the main data input via the interface controller by the subcode generating means, and the subcode A sync signal adding means for adding a sync signal to the main data to which the sub code is added by the adding means; and a margin adding means for adding a margin to the main data to which the sync signal is added by the sync signal adding means. Track the main data area and Divided into both ends of the margin area of in the data area, by dividing the main data area of each track into a plurality of blocks, by dividing one block into a plurality of sections,
The synchronization signal is recorded in the first section of each block, the subcode is recorded in the second section, and the main data is recorded in the third section.

The data streamer according to the present invention comprises header parity generating means for generating a header parity consisting of 2 bytes for detecting an error of the subcode added to the main data by the subcode adding means, and each block first A fourth section is provided between the second section and the third section, and a header parity for detecting an error of a subcode recorded in the second section is recorded in the fourth section.

The data streamer according to the present invention detects the tracking error by comparing the timing of the sync signal reproduced from the first section of each block with the reference timing, and has tracking control means for controlling the tape running system. It is characterized by being provided.

[0033]

In the data recording method according to the present invention, when data is recorded on the inclined tracks on the magnetic tape by the rotary head, one track is divided into a main data area and margin areas at both ends of the main data area, The main data area of the track is divided into a plurality of blocks, and one block is divided into a plurality of sections. Then, the synchronization signal is recorded in the first section of each block, the subcode is recorded in the second section, and the main data is recorded in the third section.

In the data recording method according to the present invention, a header parity consisting of 2 bytes for detecting an error of the subcode recorded in the second section is provided between the second section and the third section. Record in the section.

In the data recording method according to the present invention, delimiter information indicating a delimiter of main data is recorded in the second section of each block as the subcode.

In the data recording method according to the present invention, the subcode is recorded in the second section of each block of absolute position information of the recording unit of the main data.

In the data recording method according to the present invention, the discrimination information of each area on the magnetic tape defined by the tape format as the subcode is recorded in the second section of each block.

In the data recording medium according to the present invention,
One track is divided into a main data area and margin areas at both ends of the main data area, the main data area of each track is divided into a plurality of blocks, and one block is divided into a plurality of sections. The synchronization signal is held in the section, the subcode is held in the second section, and the main data is held in the third section.

Further, in the data streamer according to the present invention, when data is recorded on the inclined track on the magnetic tape by the rotary head, the main data input through the interface controller for exchanging data with the outside is input. , A sub-code from the sub-code generating means is added by the sub-code adding means, a synchronizing signal is added by the synchronizing signal adding means, and a margin is added by the margin adding means, so that one track is formed into a main data area and the main data. The main data area of each track is divided into a plurality of blocks, one block is divided into a plurality of sections, and a sync signal is recorded in the first section of each block. The subcode is recorded in the section and the main data is recorded in the third section.

In the data streamer according to the present invention, the header parity generating means generates a header parity consisting of 2 bytes for detecting an error of the subcode added to the main data by the subcode adding means, and the header parity is generated. The fourth section provided between the second section and the third section of each block is recorded.

In the data streamer according to the present invention, the tracking control means detects the tracking error by comparing the timing of the synchronizing signal reproduced from the first section of each block with the reference timing, and controls the tape running system. To do.

[0042]

Embodiments of the data recording method, data recording medium and data streamer according to the present invention will be described below in detail with reference to the drawings.

The data streamer according to the present invention is constructed, for example, as shown in FIG. The data recording method according to the present invention is implemented by this data streamer. Also,
The data recording medium according to the present invention is produced by recording data on a magnetic tape with a data streamer.

This data streamer records / reproduces data on / from an inclined track on a magnetic tape by a rotary magnetic head, and includes an interface controller 10 for exchanging data with the outside and the interface controller 10. A recording-system signal processing unit 20 that performs signal processing on the data input via the signal and converts it into a signal of a predetermined format, and a signal supplied from the recording-system signal processing unit 20 by a pair of rotary magnetic heads 31A and 31B. Recording on a slanted track on the magnetic tape 32,
A recording / reproducing unit 30 for reproducing the signal recorded on the inclined track by the rotary magnetic heads 31A and 31B.
And a reproduction system signal processing section 40 for reproducing the original data by performing signal processing on the reproduction signal reproduced by the recording / reproducing section 30, and a tracking control section 50 for controlling the tape running system of the recording / reproducing section 30. And so on.

In the data streamer of this embodiment,
The recording / reproducing unit 30 includes a pair of rotary magnetic heads 31A,
31B includes a rotating drum 31 arranged at an angle of 180 °, and the magnetic tape 3 is provided around the rotating drum 31.
The magnetic tape 32 is made to run at a predetermined running speed in a state in which 2 is wound in a range of about 90 °.
Each time the rotary drum 31 makes one rotation, as shown in FIG. 2, the pair of rotary magnetic heads 31A and 31B scans two inclined tracks T _A and T _B on the magnetic tape 32 to generate a signal. It is designed to record and play back.

Here, in this data streamer, one track is divided into three areas of a main data area and margin areas at both ends of the main data area, and the main data area is divided into 64 blocks with 195 bytes as one block. Further, a 1-byte first section for recording a synchronization signal, a 6-byte second section for recording a subcode and a block address, a 2-byte third section for recording a header parity, and data 186. One block is divided into four in the fourth section of the byte, and the subcode and the block address are recorded together with the data in each block of the main data area.

The 186-byte data recorded in the fourth section is the error correction code C having a two-dimensional structure as shown in FIG.
2, C1 are added. The error correction code C1 is added to the main data for each block and recorded, and the error correction code C2 is divided into two and recorded at both ends of the main data area of each track.

Further, in this data streamer, one frame of 2 tracks, that is, 128 blocks, is 4 frames.
6 tracks or 23 frames in 1 unit (group)
The error correction code configuration is adopted, and as shown in FIG. 4, the error correction code C2 of the data string corresponding to the track direction is arranged and recorded on both sides of the track, and the data string corresponding to the track width direction is recorded. The error correction code C3 of
Allocate to the last 2 tracks of 6 tracks and record.
It should be noted that index information for distinguishing a series of data is added to each unit.

As the subcode, a separator count, which is delimiter information indicating the delimiter of main data, a record count indicating the number of records, an area ID indicating each area defined on the tape format, and an absolute position of a recording unit. The frame number shown, the group count showing the number of recording units, the checksum, etc. are recorded.

Here, in this data streamer, as in the DDS2 format, as a tape format, as shown in FIG. 5, as a region for loading and unloading the magnetic tape, a leading region following the leader tape is formed. Physical tape start position (PBOT: Ph
A device area from the ysical Beginning of Tape) to the logical tape start position (LBOT: Logical Beginning of Tape) is defined, and a reference area and a system area are provided next to the device area. The reference area is used as a physical reference when recording a system log (history information) in the system area. Then, a data area for recording data is provided next to the system area, and E is provided next to this data area.
An OD (EOD: End of Data) area is provided. Furthermore, as shown in FIG. 6, a two-part partition having two partitions P1 and P2 each consisting of a reference area, a system area, a data area and an EOD area.
The tape is specified.

The system log (history information) of each partition P1 and P2 is recorded in the system area of the partition P1.

In the data streamer of this embodiment, the interface controller 10 transmits / receives data to / from an external host computer (not shown) via the bus 11, and the data sent from the host computer is recorded in the recording system. The data supplied to the signal processing section 20 and reproduced by the reproduction system signal processing section 40 is sent to the host computer.

Further, the recording system signal processing section 20 receives the index information by the index adding circuit 21 and the sub-code generating section 22 to which the data inputted through the interface controller 10 is supplied, and the index adding circuit 21 outputs the index information. The error correction code generation unit 23 to which the added main data is supplied, the main data to which the error correction code is added by the error correction code generation unit 23, and the subcode and block address are supplied from the subcode generation unit 22. A subcode adding circuit 24, a header parity adding circuit 25 to which main data having a subcode and a block address added by the subcode adding circuit 24 is supplied, and a header parity is added by the header parity adding circuit 25. Main data is supplied 8/1 The modulation circuit 26, the synchronization signal addition circuit 27 to which the main data converted into 10-bit data by the 8/10 modulation circuit 27 is supplied, and the margin to which the main data to which the synchronization signal addition circuit 27 is added are supplied. It comprises an adding circuit 28 and a recording amplifier 29 to which the main data added with the margin by the margin adding circuit 28 is supplied.

The index adding circuit 21 adds to the data input via the interface controller 10 index information for partitioning a series of data in units of 46 tracks, that is, 23 frames. Add.

The error correction code generating section 23 includes a memory 49, a C3 encoder 23A and a C2 encoder 23.
It consists of B and C1 encoder 23C.

In the error correction code generating section 23, the memory 49 temporarily stores the main data to which the index information is added by the index adding circuit 21 for each unit. Then, the C3 encoder 23A
Generates the error correction code C3 of the data string corresponding to the above-mentioned track width direction for the main data for each unit stored in the memory 49, and this error correction code C
3 is assigned to the last 2 tracks of the 46 tracks per unit. Further, the C2 encoder 23B generates an error correction code C2 of the data string corresponding to the track direction, divides the error correction code C2 into two, and allocates the error correction code C2 to both ends of the main data area of each track. Further, the C1 encoder 23C generates the error correction code C1 for each block described above.

In the sub-code adding circuit 24, the error-correcting code generator 23 causes the error-correcting codes C3 and C to be generated.
The subcode and block address supplied from the subcode generator 22 are added to the main data to which 2, C1 is added. As a result, the subcode and block address are assigned to the second section of each block.

Here, the subcode generating section 22 is composed of first and second subcode generating circuits 22A and 22B and a system log generating circuit 22C.

In the sub-code generating section 22, the first sub-code generating circuit 22A, based on the data input via the interface controller 10, the separator count, which is delimiter information indicating the delimiter of the main data, and the like. A record count indicating the number of records is generated. In addition, the second sub-code generation circuit 22B
Automatically generates an area ID indicating each area defined on the tape format, a frame number, a group count indicating the number of recording units, a checksum, etc. together with the block ares. Further, the system log generation circuit 22
C creates a system log (history information) for each of the partitions P1 and P2 defined as the tape format.

The header parity adding circuit 25 is also provided.
Generates 2-byte parity for error detection for the subcode and block address added to the main data by the subcode adding circuit 24, and adds the 2-byte parity to the main data. As a result, the 2-byte parity is assigned to the third section of each block.

The 8/10 modulating circuit 26 converts the main data, to which the header parity and block address are added by the header parity adding circuit 25, from 8 bits to 10 bits in 1-byte units and records the signal. So that the DC level of is maintained at about 0.

The sync signal adding circuit 27 adds a sync signal to the main data converted into 10-bit data by the 8/10 modulating circuit 26 for each block. As a result, the synchronization signal is assigned to the first section of each block.

Further, the margin adding circuit 28 adds to the main data to which the synchronizing signal adding circuit 27 is added,
Add a margin for each track. As a result, margin areas are added to both sides of each main data area for each track described above.

The main data to which a margin is added for each track by the margin adding circuit 28 is
It is supplied to the recording / reproducing unit 30 via the recording amplifier 29.

The data streamer of this embodiment is provided with the recording-system signal processing unit 20 having such a configuration, so that one track is divided into a main data area and three margin areas at both ends of the main data area. The main data area is divided into 64 blocks with 195 bytes as one block, and further, a 1-byte first section for recording a sync signal, a 6-byte second section for recording a subcode and a block address, and a header. Record parity 2
One block can be divided into four into a third section of bytes and a fourth section of 186 bytes for recording data, and a subcode can be recorded together with data in each block of the main data area. Then, as the subcode, a separator count, which is delimiter information indicating a delimiter of main data, a record count indicating the number of records, an area ID indicating each area defined on the tape format, a frame number, and a group indicating the number of recording units. You can record counts and checksums. In this way, one track is divided into three areas of the main data area and margin areas at both ends of the main data area, and the subcode is recorded together with the main data in the main data area. it can. Moreover, the reliability of the subcode can be improved by recording the 2-byte parity for detecting the error of the subcode in the third section of each block. Therefore, it is possible to provide a data recording medium with high track usage efficiency.

In this data streamer, error correction codes C2 and C1 having a two-dimensional structure are generated for the 186-byte data recorded in the fourth section, and the error correction code C1 is used as main data for each block. The error correction code C2 can be added and recorded, and the error correction code C2 can be divided into two and recorded at both ends of the main data area of each track. In this way, by recording the error correction code C1 for each block, it is possible to improve the reliability of the main data for each block. By recording the error correction code C2 for each track, the reliability of the main data for each track can be improved. Moreover, the error correction code C2 is divided into two and recorded at both end portions of the main data area for each track, so that the sliding contact with the rotary head is started / started.
You can separate the main data area from the end,
It is possible to reduce errors that occur in the data in the main data area.

Further, in this data streamer, 4 tracks are set as 1 frame for 2 tracks, that is, 128 blocks.
6 tracks or 23 frames in 1 unit (group)
The error correction code configuration is adopted, the error correction code C2 of the data string corresponding to the track direction is arranged and recorded on both sides of the track, and the error correction code C3 of the data string corresponding to the track width direction is described above. It can be recorded by being allocated to the final two tracks of the 46 tracks. Further, index information for discriminating a series of data can be added and recorded for each unit. In this way, by arranging and recording the error correction code C2 of the data string corresponding to the track direction on both sides of the track, it is possible to make the main data less likely to be destroyed and to reduce the probability of occurrence of an error in the main data. Lowering the error correction code C of the data string corresponding to the track width direction
3 makes it possible to surely correct the error in the main data.

Further, in this data streamer, the system log (history information) for each partition P1, P2
Are recorded as subcodes in the system area of the partition P1. Thus, in the system area of the partition P1, each partition P1,
By recording both system logs (history information) for each P2, the access time can be shortened and a data streamer with good operability can be realized.

Further, in the data streamer of this embodiment, the reproduction system signal processing section 40 has the recording / reproducing section 3
The sync signal detecting circuit 42 is supplied with a reproduction signal reproduced from the inclined track of the magnetic tape 32 by 0 through the reproduction amplifier 41, and 2 from the synchronization signal detecting circuit 42.
10/8 demodulation circuit 4 to which digitized reproduction data is supplied
3 and the reproduced data converted from the 10/8 demodulation circuit 43 into 8-bit data are the header parity check circuit 4
4, a sub-code separating circuit 45 supplied via the sub-code 4, an error correction processing unit 46 in which the sub-code is separated by the sub-code separating circuit 45 and reproduction data is supplied, and an error correction processing unit 46 performs error correction. It is composed of an index separation circuit 47 to which reproduction data is supplied.

In the reproducing system signal processing section 40, the synchronizing signal detecting circuit 42 detects a synchronizing signal from the reproducing signal supplied from the recording / reproducing section 30 through the reproducing amplifier 41, and outputs this synchronizing signal. The reproduced signal is binarized by the synchronized clock to generate reproduced data.

The 10/8 demodulation circuit 43 converts 10-bit data into 8-bit data for the reproduction data supplied from the sync signal detection circuit 42. 8/10 modulation circuit 2
10/8 demodulation corresponding to 6 is performed.

The header parity check circuit 4 is also provided.
In 4, the parity check of the subcode and the block address is performed using the above 2-byte header parity.
Then, the sub-code separation circuit 45 separates the correct sub-code, which has been parity-checked by the header parity check circuit 44, from the reproduced data and supplies it to a system controller (not shown).

Further, the error correction processing section 46 includes a memory 49, a C1 decoder 46A, a C2 decoder 46B and C.
3 decoder 46C.

In the error correction code generation unit 46, the memory 49 temporarily stores the main data to which the index information is added, with the main data for the 46 tracks, that is, 23 frames as one unit. It should be noted that this memory 49 is equivalent to the recording system signal processing section 2
It is shared with the error correction code generation processing unit 23 of 0.

With respect to the main data for each unit stored in the memory 49, the C1 decoder 46A
Is an error correction code C added to each block described above.
1 is used to perform error correction processing on the main data of each block. The C2 decoder 46B adds the error correction code C2 added to both ends of the main data area of each track, for the main data for each unit that has been subjected to error correction processing by the C1 decoder 46A.
Is used to perform error correction processing on the data string corresponding to the track direction. Further, the C3 decoder 46C has been subjected to error correction processing by the C2 decoder 46B.
With respect to the main data for each unit, error correction processing is performed on the data string corresponding to the track width direction using the error correction code C3 assigned to the last two tracks of the above-mentioned one unit of 46 tracks.

Further, the index separating circuit 47 separates the index information from the main data for each unit which has been subjected to the error correction processing by the error correction processing section 46 and supplies it to a system controller (not shown) or the like.

Since the data streamer of this embodiment is provided with the reproducing system signal processing section 40 having such a configuration, in the error correction processing section 46, the error correction code C1 for each block and the error correction code C2 for each track are provided.
By performing the error correction process using the error correction code C3 for each unit, the error of the main data can be surely corrected, and the main data with extremely high reliability can be obtained.

In the data streamer of this embodiment, the tracking control section 50 includes a block address detection circuit 51 to which a block address is supplied from the reproduction system signal processing section 40 via the header parity check circuit 44. The PG detection circuit 52 to which the PG pulse is supplied from the recording / reproducing section 30, the time detection circuit 53 to which the detection outputs of the block address detection circuit 51 and the PG detection circuit 52 are supplied, and the time detection circuit 53. A tracking servo circuit 54 to which a detection output is supplied,
It is composed of a capstan drive circuit 55 to which the output of the tracking servo circuit 54 is supplied.

In the tracking control unit 50, the block address detection circuit 51 detects a correct block address which is parity-checked by the header parity check circuit 44, and outputs a detection output indicating the detection timing to the time detection circuit 53. Supply. Also,
The PG detection circuit 52 detects a PG pulse indicating the rotation phase of the rotary drum 31 supplied from the recording / reproducing unit 30, and supplies a detection output indicating the detection timing to the time detection circuit 53. The time detection circuit 53 is
The time between the timing when the block address detection circuit 51 detects a predetermined block address and the timing when the PG detection circuit 52 detects the PG pulse is detected. Here, when an inclined track on the magnetic tape 32 is scanned by the rotary magnetic heads 31A and 31B having a predetermined rotation phase, as shown in FIG. 7, the scanning distance from the tape edge of the track to a predetermined block is just tracking. In the state of 1, the value is L, but when there is a tracking error, it changes by ± Δ depending on the tracking error. Therefore, the time detected by the time detection circuit 53 changes from the time in the just tracking state according to the tracking error.

Then, the tracking servo circuit 54
Detects a time difference between the reference time and the time detected by the time detection circuit 53, that is, a tracking error, and sets the tracking error to 0 based on the detection output. As described above, the capstan drive circuit 55 for driving the capstan motor of the tape running system of the recording / reproducing unit 30 is controlled.

The data streamer of this embodiment is provided with the tracking control section 50 having such a configuration, so that tracking control can be performed without recording the ATF signal for tracking control on the magnetic tape.
Therefore, since it is not necessary to secure a section for recording the ATF signal for tracking control, the data amount of the main data can be increased correspondingly, and the utilization efficiency of the track can be further improved.

[0082]

According to the data recording method of the present invention, when data is recorded on the inclined tracks on the magnetic tape by the rotary head, one track is divided into a main data area and margin areas at both ends of the main data area. , The main data area of each track is divided into multiple blocks,
One block is divided into a plurality of sections. Then, the sync signal is recorded in the first section of each block, the subcode is recorded in the second section, and the main data is recorded in the third section.
The usage efficiency of the truck can be improved. Further, a header parity consisting of 2 bytes for detecting an error of the subcode recorded in the second section is added to the second section and the third section.
By recording in the fourth section provided between the section and the section, the reliability of the subcode can be improved.

Therefore, according to the present invention, there is provided a data recording method for recording data on a slanted track on a magnetic tape by a rotary head, wherein subcode is recorded together with main data, and the track can be used efficiently. It is possible to provide a data recording method for recording parity for error detection of a subcode.

Further, in the data recording medium according to the present invention,
One track is divided into a main data area and margin areas at both ends of the main data area, the main data area of each track is divided into a plurality of blocks, and one block is divided into a plurality of sections. The synchronization signal can be held in the section, the subcode can be held in the second section, and the main data can be held in the third section. This allows
According to the present invention, there is provided a data recording medium in which data is recorded on a tilted track on a magnetic tape by a rotary head, in which a subcode is recorded together with main data, and the track usage efficiency is high. You can

Further, in the data streamer according to the present invention, when data is recorded on the slanted track on the magnetic tape by the rotary head, the main data input via the interface controller for exchanging data with the outside is added to the main data. , A sub-code from the sub-code generating means is added by the sub-code adding means, a synchronizing signal is added by the synchronizing signal adding means, and a margin is added by the margin adding means, so that one track is formed into a main data area and the main data. The main data area of each track is divided into a plurality of blocks, one block is divided into a plurality of sections, and a sync signal is recorded in the first section of each block. Use the track because the subcode is recorded in the section and the main data is recorded in the third section. It is possible to increase the rate. Also,
By recording a header parity consisting of 2 bytes for error detection of the subcode recorded in the second section in the fourth section provided between the second section and the third section,
The reliability of the subcode can be improved.

Therefore, according to the present invention, the data streamer records the data on the inclined track on the magnetic tape by the rotary head, and records the sub-code together with the main data, so that the track can be used efficiently and further.
A data streamer may be provided that also records the parity for subcode error detection.

Further, in the data streamer according to the present invention, the tracking control means detects the tracking error by comparing the timing of the synchronizing signal reproduced from the first section of each block with the reference timing, and the tape running system. Is controlled, the tracking control can be performed without recording a special signal for the tracking control.

[Brief description of drawings]

FIG. 1 is a block circuit diagram showing a configuration of a data streamer according to the present invention.

FIG. 2 is a diagram showing a track format of a magnetic tape on which data is recorded by the data streamer.

FIG. 3 is a diagram showing a data structure of one track of data recorded on a magnetic tape by the data streamer.

FIG. 4 is a diagram showing a data structure of one unit of 46 tracks of data recorded on a magnetic tape by the data streamer.

FIG. 5 is a diagram showing a tape format of a magnetic tape on which data is recorded by the data streamer.

FIG. 6 is a diagram showing a tape format of a two-partition tape of the magnetic tape.

FIG. 7 is a diagram illustrating a principle of detecting a tracking error by a tracking control unit in the data streamer.

FIG. 8 is a diagram showing a DAT format.

FIG. 9 is a diagram showing a block format of main data in the DAT format.

FIG. 10 is a diagram showing a data array by interleaving in the DAT format.

FIG. 11 is a diagram showing the structure of an error correction code of main data in the DAT format.

[Explanation of symbols]

 10 interface controller 20 recording system signal processing unit 21 index addition circuit 22 subcode generation unit 22A first subcode generation circuit 22B second subcode generation circuit 22C system log generation circuit 23 error correction code generation unit 23A C3 encoder 23B C2 Encoder 23C C1 Encoder 24 Subcode addition circuit 25 Header parity addition circuit 26 8/10 Modulation circuit 27 Synchronous signal addition circuit 28 Margin addition circuit 30 Recording / reproducing unit 31 Rotating drum 31A, 31B Rotating magnetic head 32 Magnetic tape 40 Magnetic tape 40 Reproducing system signal processing Circuit 42 Synchronization detection circuit 43 8/10 demodulation circuit 44 Header parity check circuit 45 Subcode separation circuit 46 Error correction processing unit 46A C1 decoder 46B C2 decoder 46C C3 decoder 4 7 Index separation circuit 49 memory

Claims (9)

[Claims] 1. A data recording method for recording data on a tilted track on a magnetic tape by a rotary head, wherein one track is divided into a main data area and margin areas at both ends of the main data area, and The main data area is divided into a plurality of blocks, one block is divided into a plurality of sections, the sync signal is recorded in the first section of each block, the subcode is recorded in the second section, and the main data is recorded in the third section. A method for recording data, characterized by recording. 2. A fourth section is provided between the second section and the third section of each block, and a header parity consisting of 2 bytes for detecting an error of a subcode recorded in the second section is provided as the fourth section. The data recording method according to claim 1, wherein the data is recorded in a section. 3. The data recording method according to claim 1, wherein delimiter information indicating a delimiter of main data is recorded in the second section of each block as the subcode. 4. The data recording method according to claim 1, wherein the sub-code is recorded in a second section of each block of absolute position information of a recording unit of main data. 5. The discriminating information of each area on the magnetic tape defined by the tape format as the subcode is recorded in the second section of each block.
Data recording method described. 6. A magnetic tape in which data is recorded on inclined tracks by a rotary head, wherein one track is divided into a main data area and margin areas at both ends of the main data area, and the main data area of each track is It is divided into a plurality of blocks, one block is divided into a plurality of sections, and a synchronization signal is recorded in the first section of each block.
A data recording / recording medium comprising a magnetic tape in which a subcode is recorded in a section and main data is recorded in a third section. 7. A data streamer for recording data on a tilted track on a magnetic tape by a rotary head, an interface controller for exchanging data with the outside, and main data input via the interface controller. A subcode generating means for generating a subcode to be added to the subcode, a subcode adding means for adding the subcode from the subcode generating means to the main data input via the interface controller, and the subcode adding means. There is provided a sync signal adding means for adding a sync signal to the main data to which the sub code is added, and a margin adding means for adding a margin to the main data to which the sync signal is added by the sync signal adding means. Data area and main data area The main data area of each track is divided into a plurality of blocks, one block is divided into a plurality of sections, and a sync signal is recorded in the first section of each block. A data streamer characterized by recording a subcode in a section and recording main data in a third section. 8. The header parity generating means for generating a header parity consisting of 2 bytes for detecting an error of the subcode added to the main data by the subcode adding means is provided, and each block has a second section and a third section. The data streamer according to claim 7, wherein a fourth section is provided between the first and second sections, and a header parity for detecting an error of a subcode recorded in the second section is recorded in the fourth section. 9. A tracking control means for controlling a tape running system by detecting a tracking error by comparing the timing of a sync signal reproduced from the first section of each block with a reference timing. The data streamer according to claim 7.