KR19980027215U - Record compensator for high density recording - Google Patents

Abstract

The present invention relates to a recording compensator for high density recording, particularly comprising: edge detection means for detecting the leading edge of a data pulse train recorded on a recording medium in synchronization with a clock signal; Train generating means for generating only a clock signal delayed by a half cycle among the pulse trains of the clock signal corresponding to the valid period of each data pulse train; And recording compensation means for combining the detection signal outputted from the edge detection means and the signal outputted from the train generating means to extend the pulse width of the first end of the recording signal to be marked on the optical disc and to output it. do.

In the present invention, in recording a Mark Length with data information on an optical disc, only a tip portion of the Mark Length to be recorded is transmitted by making a large current to make the recording more dense, resulting in a higher density of the data. Accurate detection of edges prevents pit edge shifts and jitters, resulting in accurate data.

Description

Record compensator for high density recording

The present invention relates to an optical disk apparatus capable of recording / reproducing, and more particularly, to a recording apparatus for recording a data area by shooting a laser beam onto a track on an optical disk to generate a mark length.

In general, the recording method of the optical disk device is divided into write-once recording and write-once recording. Write-once recording discs cannot be erased once or write new data again. The disc can be used to rewrite new data as many times as possible in the same data area.

The write-once recording method uses a common method of making pits with laser light and irradiates the recording material of the disc track with laser light to raise the temperature above the melting point or decomposition point of the recording layer to pierce the pits.

When the weak laser light is irradiated, the reflected light of the portion where the pit is not drilled and the portion where the pit is drilled is different, so that the intensity of the reflected light is detected by the photodiode to reproduce the signal.

Such a write-once-type disk has a feature that high-density recording is possible, and recording is required for stability as the recording film is longer than 10 years.

1 is a block diagram showing a recording apparatus of a conventional optical disk, wherein recording data processing means 10 for processing data to be recorded on the optical disk, and data output from the recording data processing means 10 in a signal form suitable for the optical disk. A modulating means 20 for converting, a recording amplifying means 30 for adjusting a current of a laser beam to record a modulated signal output through the modulating means 20, and an output through the recording amplifying means 30 And a recording head 40 capable of recording the modulated signal onto the optical disc track by the current that is generated.

In the recording apparatus of the optical disc configured as described above, data is signal-processed through the recording data processing means 10 and output as a data bit string. Data of the bit string is input to the modulation means 20, converted into a mark string, and output.

The write amplification means 30 converts the current into a square wave shape and applies it to the semiconductor laser according to the size of the mark length output through the modulating means 20.

Since the recording head 40 changes the laser light differently according to the current output through the recording amplifying means 30, data of desired size is generated by generating pits of different sizes in the optical disc.

In the recording method of such an optical disc apparatus, data reproduction is accurately performed only when the edge of the pit is accurately detected.

However, when the mark length reading is read, the mark interval is narrow, so pit-shaped distortion occurs, causing jitter due to pit edge shift or waveform interference.

Therefore, when reproducing the data of the write-once-type recording method, the detection window is reduced due to the pit edge shift and jitter according to the mark length, resulting in waveform interference between the reproduction signals, thereby obtaining accurate data. There is a problem that high density cannot be achieved even in data recording.

The purpose of the present invention is to accurately record the edge of the pit during data recording so as to solve the problem of the waveform interference between the reproduced signal due to the pit edge shift and jitter as described above. The present invention provides a recording compensator for high density recording that can prevent jitter in advance.

In order to achieve the above object, the apparatus of the present invention comprises: edge detection means for detecting the leading end of a data pulse train recorded on a recording medium in synchronization with a clock signal; Train generating means for generating only a clock signal delayed by a half cycle among the pulse trains of the clock signal corresponding to the valid period of each data pulse train; And recording compensation means for combining the detection signal outputted from the edge detection means and the signal outputted from the train generating means to extend the pulse width of the first end of the recording signal to be marked on the optical disc and to output it. do.

1 is a block diagram showing a recording apparatus of a conventional optical disc.

2 is a block diagram showing a recording compensator for high density recording according to the present invention.

3 is a waveform diagram illustrating FIG. 2.

* Description of the symbols for the main parts of the drawings *

10: recording data processing means. 20: modulation means.

30: Record amplification means. 40: recording head.

100: edge detection means. 110: train generation means.

120: record compensation means.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram showing a recording compensator for high-density recording according to the present invention, in which a data pulse string A is raised by receiving a data pulse string A to be recorded on an optical disc track in synchronization with a clock signal B; Edge detecting means 100 for detecting an edge, train generating means 110 for generating a train signal in which the clock signal B is delayed half a period during the high level of the data pulse string A, and the edge detecting means ( And a compensating means 120 for generating a recording signal E that becomes low level only when the two signals are low level by logically combining the detection signal C and the train signal D outputted at 100). .

3 is a waveform diagram for explaining FIG. 2, where A represents a data pulse string and B represents a clock signal. C denotes an edge detection signal, D denotes a train signal and E denotes a recording signal.

2 to 3, the data pulse string A having different size information is generated on the rising edge of the clock signal B to generate a mark length to be recorded on the optical disk track. It inputs to the edge detection means 100 synchronously.

The detection signal C is generated when the data pulse string A is the rising edge through the edge detection means 100.

When the data pulse train A is recorded on the optical disk, accurate data can be obtained at the time of data reproduction only when the edge of the pit is correct. Therefore, a large current is required at the beginning of marking the data on the optical disk. Therefore, the train generating means 110 does not generate the train signal D for half a period of the clock signal B when the data pulse string A is at a high level. Generates a train signal (D) opposite to the phase of.

In addition, the detection signal C output through the edge detection means 100 and the train signal D output through the train generation means 110 are input to the recording compensation means 120 so that the two signals are input. Since only the low level becomes the low level, only the pulse width of the first end of the recording signal E to be marked on the optical disc is increased and output.

The recording signal E output through the recording compensating means 120 generates a large amount of current only during one clock cycle and generates a recording current with a trained pulse magnitude during the remaining clock periods. The amount of laser light varies accordingly.

By the recording signal E, the laser irradiates a large amount of light only at the beginning of the data pulse train A to be marked on the optical disk, thereby making the pit clear, thereby achieving high recording density.

In addition, since the edge of the pit can be detected accurately during optical disc reproduction, the pit edge shift or jitter can be reduced, so that accurate data can be obtained.

In the present invention, in recording a Mark Length with data information on an optical disc, only the tip portion of the Mark Length to be recorded sends a large current to make the recording more dense. Accurate detection of edges prevents pit edge shifts and jitters, resulting in accurate data.

Claims (1)

Edge detection means for detecting the leading end of the data pulse train recorded on the recording medium in synchronization with a clock signal; Train generating means for generating only a clock signal delayed by a half cycle among the pulse trains of the clock signal corresponding to the valid period of each data pulse train; And recording compensation means for combining the detection signal outputted from the edge detection means and the signal outputted from the train generating means to extend the pulse width of the first end of the recording signal to be marked on the optical disc and to output it. Record compensator for high density recording.