JPS61168173A - Recording and reproduction system - Google Patents

Abstract

PURPOSE:To detect a synchronizing pattern stably and to demodulate data by generating and recording plural kinds of synchronizing patterns on a recording medium, detecting the synchronizing patterns during reproduction, and judging a demodulation start point when even one detection output is generated. CONSTITUTION:A clock synchronizing burst pattern, three kinds of synchronizing patterns which differ by two bits respectively, modulated digital data, and a file end pattern are inputted from a synchronizing burst pattern generator 11, a synchronizing pattern generator 12, a demodulator 13 for data, and a file pattern generator 14 to a recorder 30 through contacts (a)-(c) of a switch 20, so that they are recorded on the recording medium 40. A signal reproduced by a reproducer 50 from the recording medium 40 is inputted to a shift register 62 and a synchronizing pattern from a synchronizing pattern generator 64 is compared by a comparator 63 with the contents of the register 62 as to every synchronizing pattern SYNC.BYTT and an AND gate 17 is opened when even one pattern is coincident, so that the data is demodulated by a demodulator 80.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a recording and reproducing method for recording and reproducing digital information on a magnetic medium, a magneto-optical medium, and an optical medium. In particular, it relates to a method for stabilizing demodulation by making synchronization patterns redundant.

〔overview〕

In a digital information recording and reproducing method, the present invention configures a synchronization pattern section of a recording format to continuously record a plurality of different synchronization patterns, and detects even one of the plurality of synchronization patterns during playback. If it is done,
By determining the starting point of data demodulation, it is possible to stably detect synchronization patterns and demodulate data.

[Conventional technology]

FIG. 6 shows a recording format of a conventional recording/reproducing apparatus. As shown in FIG. 6, the conventional recording/reproducing apparatus has a recording format consisting of a clock synchronization burst pattern section 1 that generates a clock for data demodulation, a synchronization pattern section that indicates the start point of data, and a data section 3 following it. has been done.

[Problem that the invention seeks to solve]

However, in such conventional recording and reproducing devices, the synchronization pattern section 2 is generally composed of a plurality of bits, and for example, when it is composed of 8 bits, those 8 bits are completely synchronized with the synchronization pattern 5YNC- If it does not match BYTE, it will not be detected as synchronization pattern 5YNC-BYTE.

Therefore, the synchronization pattern section 2 may not be recorded correctly during recording due to a defect in the medium or the recording device, or the synchronization pattern section 2 may not be recorded correctly during recording due to a defect in the playback device or noise during playback.
is not detected correctly, the following data DA
TA had the disadvantage that it could not be demodulated.

The present invention solves the above-mentioned drawbacks, and aims to provide a recording/reproducing method that can stably detect synchronization patterns and demodulate data.

[Means for solving problems]

The present invention includes a synchronization pattern generator that generates a synchronization pattern;
A recorder that stores the synchronization pattern as part of digital information on a recording medium, a regenerator that reproduces the digital information recorded on the recording medium, and a detector that detects the synchronization pattern from the output of the regenerator. In a digital information recording and reproducing method that includes a determiner that determines the data demodulation start point based on the detection output of the detector, the synchronization pattern generator generates multiple types of synchronization patterns whose pattern configurations differ from each other by two or more bits. The detector is provided with a detection means for detecting any of the plurality of types of synchronization patterns mentioned above as a synchronization pattern, and the determination device is configured to detect a synchronization pattern based on the detection output of any one of the detection means. The present invention is characterized by comprising determining means for determining the demodulation start point of the data.

[For production]

In the present invention, during recording, a synchronization pattern generating means generates a plurality of types of synchronization patterns that differ from each other by two or more bits, and the recording device records the patterns on a recording medium. At the time of reproduction, the detection means detects a plurality of types of synchronization patterns that differ by two or more bits from the above-mentioned pressure reproduced by the regenerator, and if the determination means has at least one detection output, the demodulation start point is determined based on this. , it is possible to stably detect synchronization patterns and demodulate data.

〔Example〕

Embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram of a recording device of a recording and reproducing apparatus according to a first embodiment of the present invention. FIG. 2 is a block diagram of the reproducing device of the recording/reproducing apparatus according to the embodiment of the present invention. In FIG. 1, a clock synchronous burst pattern PLO.5YNC from a clock synchronous burst pattern generator 1 is connected to a contact a of a switch 20.

Here, the feature of the present invention is the synchronization pattern generation portion surrounded by a dashed line. In other words, the synchronization pattern generator 12 generates not one type of synchronization pattern, but
In this example, three types of synchronization patterns are generated. One synchronization pattern has an 8-bit configuration, but each of the three types of synchronization patterns is configured to differ from each other by at least 2 bits. These three types of synchronization patterns 5YNC-BY
TE+ to 5YNC/BYTE3 are connected to the contacts of the switch 20. Digital data is sent to the modulator 13 from outside the diagram.
The digital data DATA modulated from the modulator 13 is connected to the contact C of the switch 20 . Also,
The file end pattern EOF from the file end pattern generator 14 is connected to the contact d of the switch 20. Switch 20
The contact e is connected to the input of the recorder 30, and the clock synchronization burst pattern 7 PLO-5YNC1 synchronization pattern 5YN
C-BYTE+~5YNC-BYTL, modulated digital data DATA and file end pattern EOF
are input sequentially.

The output of the recorder 30 is connected to a recording medium 40 and recorded.

In FIG. 2, from the recording medium 40, clock synchronization pattern PLO・5YNC, synchronization pattern 5YNC-BYTE+
-5YNC/BYTE3, modulated digital data [1ATA and file end pattern EOP are reproducer 5
Connected to the 0 input. A clock synchronous burst pattern P1.0.5YNC from the regenerator 50 is connected to the power of the clock generator 61 of the detector 60.

Here, the feature of the present invention is the synchronization pattern detection and demodulation start point determination portion surrounded by a dashed line. That is, a clock signal from clock generator 61 is connected to a clock input of shift register 62 . Synchronization pattern 5YNC-BYTE+~5YNC-BYTE from the regenerator 50
3 is connected to the input of shift register 62. Regenerator 5
The digital data DATA modulated from 0 and the file end pattern EOF are processed by the AND gate 71 of the determiner 70.
connected to one input of the Synchronous pattern 5YNC-BYTE+ ~5YNC・BYTE from shift register 62
3 are connected to respective inputs of comparator 63, respectively. In addition, the synchronization pattern generator 64 generates a synchronization pattern 5YNC.
BYTE+ to 5YNC-BYTE are connected to respective inputs of comparator 63, respectively. The comparison results from the comparators 63 are connected to respective inputs of the OR gates 72, respectively. The output to the OR gate 72 is the AND gate 7
connected to the other input of 1. The output of AND gate 71 is connected to the input of demodulator 80, and demodulated digital data is output from demodulator 80.

The operation of the recording/reproducing apparatus having such a configuration will be explained. FIG. 3 shows the recording format of the recording/reproducing apparatus of the present invention. In FIG. 3, the clock synchronization burst pattern section 1 consists of several tens of bytes, r 111-----
-1'', r 10101-----01 J or r o---1---0''. However, it is sufficient that the clocks are sufficiently synchronized, and the pattern and length are not specified.

Next, the feature of the present invention is that the synchronization pattern 5YNC
- Provide multiple types of BYTE. In the example shown in Figure 3, there are three synchronization patterns of 8 bits, 5YNC-BYTE+, 5YN.
C.BYTE2.5YNC-BYT[3i are arranged consecutively. After that, data section 3 (error correction code E
(including CC) are placed. The length of this data section 3 may be a fixed number of bytes or a variable number of bytes. It is generally followed by an end-of-file pattern EOF indicating the end of the data.

FIG. 4 is a diagram showing a synchronization pattern of the recording/reproducing apparatus of the present invention. In FIG. 4, the recording format is three synchronization patterns 5YNC-BYTE+ to 5YNC-BYTE.

Each of the bits is composed of 8 bits, and the patterns (bit configurations) are different from each other by two or more bits. Furthermore, this synchronization pattern 5YNC-BYTE is required to be a pattern that never occurs in the data section 3.

The "" mark indicates a clock missing position. Sync pattern S
Y? JG: -BYTE is detected, then the data part 3
It takes 16 clocks (after 16 bits) to reach the data section 3, and it takes 8 bits from the detection of the synchronization pattern 5YNC/BYTE2 to the data section 3. Similarly, after the synchronization pattern 5YNC-BYTE is detected, the data section 3 is started next. Therefore, even if the synchronization pattern 5YNC/BYTE is disturbed due to noise in the reproduced signal due to a recording problem, a defect in the medium, or noise during playback, it is accurate if any one of the synchronization patterns 5YNC/BYTE is detected. The beginning of the data section 3 can be found, and the demodulation of the data section 3 can be performed without any problem. Also, since there is a difference of 2 bits or more between synchronization patterns 5YNC-BYTE, synchronization patterns 5YNC-BYTI! The probability of erroneous detection in between is also very low (can be suppressed). Therefore, even a device with a relatively low error rate can stably determine the starting point of the data section 3.

FIG. 5 is a diagram showing the bit error occurrence interval of the recording generating device. In FIG. 5, "x" marks indicate error bits, and T is the error occurrence interval (number of bits). in general,
As the recording surface density increases, the bit error rate due to the quality of the medium increases. Therefore, there are more opportunities for errors to occur in the synchronization pattern section 2, making demodulation of data impossible.

Here, the optimal number of synchronization patterns 5YNC/BYTE will be explained. Generally, bit errors tend to occur uniformly on the recording surface, but for example, as shown in Figure 5, the distance T from one error group to the next error group is
(number of bits) is less than 8 bits, it is sufficient to set the number of synchronization patterns 5YNC-BYTE to 3, and there is a very small probability that all three synchronization patterns 5YNC-BYTE will not be detected. The synchronization pattern 5YNC-BYTE can be detected stably.

In FIG. 1, signals from a clock synchronization burst pattern generator 11, a synchronization pattern generator 12, a data modulator 13, and a file end pattern generator 14 are sequentially switched by a switch 20 and recorded on a recording medium 40. Record at 30.

In FIG. 2, the signal reproduced by the regenerator 50 from the recording medium 40 is input to the shift register 62, and the synchronization pattern 5YNC-BYTE from the synchronization pattern generator 64 and the contents of the shift register 62 are input to the comparator 63. A comparison is made each time a signal is input to the shift register 62 for each synchronization pattern 5YNC-BYTE, .about.5YNC-BYTE.

If at least one synchronization pattern 5YNC-BYTE is compared and a match is found, the AND gate 71 is opened, and since the next signal is data DATA, it is input to the demodulator 80 and demodulated.

〔Effect of the invention〕

As explained above, by configuring the synchronization pattern section with a plurality of types of patterns, the present invention can stably detect the synchronization pattern even on a medium with a high bit error rate, and has the excellent effect of demodulating data. be.

[Brief explanation of drawings]

FIG. 1 is a block diagram of a recording device of a recording and reproducing apparatus according to an embodiment of the present invention. FIG. 2 is a block diagram of the reproducing device of the recording/reproducing apparatus according to the embodiment of the present invention. FIG. 3 shows the recording format of the recording/reproducing apparatus of the present invention. FIG. 4 is a diagram showing a synchronization pattern of the recording/reproducing apparatus of the present invention. FIG. 5 is a diagram showing the bit error occurrence interval of the recording/reproducing apparatus. FIG. 6 shows the recording format of a conventional recording/playback device. 1... Clock synchronization burst pattern section, 2... Synchronization pattern section, 3... Data section, 4... File end pattern section. '11... Clock synchronous burst pattern generator (PLO
・5YNCG), 12.64... Synchronization pattern generator (SYNC/BYTEG), 13... Modulator, 1
4...File end pattern generator (EOF G)
, 20...Switcher, 30...Recorder, 40...Recording medium, 50...Regenerator, 60...Detector, 61...
...Clock generator (PLOG) 62...Shift register (SR), 63...Comparator (GOMP)
, 70... Determiner, 71... AND gate, 72...
...OR gate, 80...Demodulator, DATA...Data, PLO/5YNC...Clock synchronization burst pattern, 5YNC/BYTE...Synchronization pattern, a, b,
c, d, e... contacts of the switch (20). Patent applicant: NEC Corporation 31,

Claims (1)

[Claims] (1) A synchronization pattern generator that generates a synchronization pattern, a recorder that stores this synchronization pattern on a recording medium as part of digital information, a regenerator that reproduces the digital information recorded on this recording medium, and In a digital information recording and reproducing method that includes a detector that detects a synchronization pattern from the output of a regenerator and a determiner that determines a data demodulation start point based on the detection output of this detector, the synchronization pattern generator is The detector includes a synchronization pattern generating means for generating a plurality of types of synchronization patterns whose pattern configurations differ from each other by two or more bits, the detector includes a detection means for detecting any of the plurality of types of synchronization patterns as a synchronization pattern, and the detector A recording/reproducing method characterized in that the recording/reproducing method comprises a determining means for determining a demodulation start point of the data based on the detection output of any one of the detecting means.