KR19990069679A - Adaptive recording method and apparatus for high density optical recording device - Google Patents

Abstract

An adaptive recording method for a high density optical recording device and an apparatus thereof are disclosed. A discriminator for determining the size of the previous space and the current mark of the input data, the generator for generating the adaptive recording pulse by controlling the waveform of the recording pulse according to the size of the previous space and the size of the current mark, and the adaptive recording pulse. The present invention includes a current driver for driving a laser diode by converting the current signal into a current signal according to the driving level of the optical output of each channel, according to the current mark size and the size of the previous space of the input NRZI data. By varying the width of the first and last pulses, jitter is minimized to improve system reliability and performance.

Description

Adaptive recording method and apparatus for high density optical recording device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an adaptive recording method and apparatus therefor for a high density optical recording device, and more particularly, to an adaptive recording method and apparatus for optimizing optical power of a laser diode.

In the multimedia era, high-capacity recording media are required, and optical recording apparatuses using such high-capacity recording media include MODD (Magnetic Optical Disc Driver) and DVD-RAM (Digital Versatile Disc Random Access Memory) drivers.

Such optical recording apparatuses require an optimal system state as the recording density increases and require precision. In general, it is important to minimize such jitter in order to achieve high density recording since the recording capacity increases, the time-axis oscillation (hereinafter referred to as jitter) of the recording pulse with respect to the radial tilt becomes large. .

Conventionally, as shown in Fig. 1 (e) for input NRZI (Non Return to Zero Inversion) data composed of 3T, 5T, 11T, etc., the recording mark length as shown in Fig. 1A is shown. An overwrite pulse was constructed and recorded in the state specified in the book. Here, the NRZI data is divided into a mark and a space, which is called a cooling pulse because the laser diode is off in this space period. The recording marks of other 3T, 4T, ..., 14T NRZI data in units of 1L (L: 1 bit length) are recorded by changing only the number of multi-pulses without changing the first, last and cooling pulses.

That is, the reproduction light output (read power (b) of FIG. 1), the peak light output (also called write light output: (c) of FIG. 1) and the bias power output (aka Also referred to as erase light output: The waveform of the recording pulse shown in FIG. 1E is formed by the combination of FIG.

This recording pulse waveform is also the same as the first generation, 2.6 GB (Giga Byte) DVD-RAM standard. That is, according to the 2GB DVD-RAM standard, the waveform of the recording pulse is composed of the first pulse, the multi pulse chain and the last pulse, and the rising edge of the first pulse of the basic recording pulse is higher than the rising edge of the recording mark. T / 2 delayed point, the rising edge of this first pulse can be shifted back and forth in units of 1 ns (nono second), the last pulse can also be shifted back and forth in units of 1 ns. Heat accumulation at the rear end of the recording mark is reduced to prevent deformation of the recording mark.

In such a structure of the recording pulse, a recording pulse waveform is produced and used irrespective of the preceding space and the following space of the recording mark.

Therefore, according to the NRZI data input when configuring and recording a recording pulse as shown in Fig. 1E, in particular, when data having a long recording mark length where heat accumulation may occur at the rear end of the recording mark is continuous. Jitter occurs. This is the biggest factor that degrades the performance of the system, there is a problem that will be difficult to use in the future high-density DVD-RAM, for example, the second generation, 4.7GB DVD-RAM.

In order to solve the above problems, an object of the present invention is to provide a method for configuring and recording an adaptive recording pulse according to the size of the current mark and the size of the previous space of the input NRZI data.

Another object of the present invention is to provide an apparatus for configuring and recording an adaptive recording pulse according to the size of a current mark and a size of a previous space of NRZI data input in a high density optical recording device.

In order to achieve the above object, the adaptive recording method according to the present invention is a method for controlling the light output of a laser diode, by controlling the waveform of the recording pulse in accordance with the size of the previous space and the current mark of the input data Generating a controlled write pulse and converting the controlled write pulse into a current signal according to the drive level of the optical output of each channel to drive the laser diode.

In order to achieve the above another object, the adaptive recording apparatus according to the present invention is an apparatus for controlling the light output of a laser diode, comprising: a discriminator for discriminating the size of the previous space and the current mark of the input data; The generator generates the adaptive recording pulse by controlling the waveform of the recording pulse according to the size of the space and the size of the current mark, and converts the adaptive recording pulse into a current signal type according to the drive level of the optical output of each channel to generate a laser diode. And a current driver for driving.

1A to 1E are waveform diagrams showing the configuration of a conventional recording pulse.

2 is a block diagram according to an embodiment of an adaptive recording apparatus for a high density optical recording apparatus according to the present invention.

3A to 3C are waveform diagrams of adaptive recording pulses recorded by the adaptive recording apparatus shown in FIG.

Hereinafter, with reference to the accompanying drawings, a description will be given of a preferred embodiment of an adaptive recording method and a device for a high density optical recording apparatus according to the present invention.

The recording pulse waveform for the second generation, i.e., 4.7 GB DVD-RAM, will be used with adaptive recording pulses taking into account the space before and / or after the recording mark. Therefore, the present invention generates an adaptive recording pulse using the size of the current recording mark and the size of the previous space.

That is, the adaptive recording apparatus according to the present invention includes a data discriminator 102, a recording waveform controller 104, a microcomputer 106, a recording pulse generator 108, and a current driver 110 as shown in FIG. It consists of.

That is, the data discriminator 102 determines the input NRZI data, and the recording waveform controller 104 determines the waveform of the recording pulse according to the result determined by the data discriminator 102 and the land / groove signal. To correct. The microcomputer 106 initializes the recording waveform controller 104 or controls the data stored in the recording waveform controller 104 to be updated in accordance with recording processing conditions. The write pulse generator 108 generates a write pulse according to the output of the write waveform controller 104, and the current driver 110 generates a write pulse generated by the write pulse generator 108 according to the light output level of each channel. It converts into a signal to drive the laser diode.

Next, the operation of the apparatus shown in FIG. 2 will be described.

In Fig. 2, the data discriminator 102 inputs the NRZI data to the front space corresponding to the previous pulse (called the previous space) and the size of the mark corresponding to the current recording pulse (hereinafter referred to as the current mark). Is obtained and applied to the recording waveform controller 104.

The recording waveform controller 104 shifts the rising edge of the first pulse back according to the size of the previous space and the size of the current mark applied from the data discriminator 102, or changes the last pulse according to the size of the current mark. The falling edge is shifted back and forth to change the position of the recording waveform having the optimum light output to generate data corresponding to the width of the first pulse of the current mark and data corresponding to the width of the last pulse. At this time, the rising edge of the first pulse of the basic recording pulse of the present invention is synchronized with the rising edge of the current mark, and the duration in which the rising edge of the first pulse is shifted backward for optimum light output of the laser diode is reproduced. The period of shifting the falling edge of the last pulse back and forth is also filled with the regenerative light output.

In addition, the recording waveform controller 104 has the rising edge of the first pulse of the current mark in accordance with a LAND / GROOVE signal coming from outside indicating whether the input NRZI data is the data of the land track or the groove track. And the falling edge of the last pulse of the current mark. The reason for this is to create a recording waveform in consideration of this since the optimum light output of each land and groove is different.

The recording waveform controller 104 may be configured as a memory or logic circuit in which data corresponding to the pulse width of the first pulse and the pulse width of the last pulse is stored according to the current mark size and the previous space size of the input NRZI data. The memory may also store pulse width data reflecting the case where the first pulse width data and the last pulse width data of the recording pulse are the land track and the groove track, respectively. The microcomputer 106 initializes the recording waveform controller 104 or controls the pulse width data adjusted according to the recording conditions to be updated.

The pulse width data controlling the waveform of the recording pulse in this way is applied to the recording pulse generator 108. The recording pulse generator 108 generates an adaptive recording pulse in accordance with the pulse width data controlling the recording pulse waveform applied from the recording waveform controller 104, so that each channel (playback, peak, bias) for this adaptive recording pulse is generated. A control signal for controlling the flow of current is applied to the current driver 110.

The current driver 110 converts the driving level of the optical output of each input channel (regeneration, peak, bias) into a current by a control time corresponding to a control signal for controlling the flow of each channel current, and flows the current through a laser diode. The continuous on and off operation of the diodes heats the recording medium and records the desired recording waveform.

3 (a) shows NRZI data to be input, which is divided into a mark and a space. Fig. 3B shows the basic recording waveform of the present invention, in which the rising edge of the current mark and the rising edge of the first pulse of the recording pulse are synchronized.

3 (c) shows a waveform of an adaptive recording pulse proposed in the present invention. The first pulse of this adaptive write pulse waveform can be shifted backwards according to the combination of the previous space size (T ₁ ) and the current mark length (T ₂ ), and the last pulse is shifted back and forth according to the current mark length (T ₂ ). can do. However, the present invention has an advantage of reducing the time delay since the current mark is processed without considering the size T ₃ of the space after the current mark.

The novel adaptive recording pulse waveform proposed in the present invention enables use in most high density optical recording devices.

As described above, the present invention changes the width of the first pulse and the last pulse of the recording pulse according to the size of the current mark and the size of the previous space of the input NRZI data to minimize jitter to improve the reliability and performance of the system. It works.

Claims (16)

In a method of controlling the light output of a laser diode: (a) generating a controlled recording pulse by controlling the waveform of the recording pulse according to the size of the previous space of the input data and the size of the current mark; And and (b) converting the controlled write pulse into a current signal according to the drive level of the optical output of each channel to drive a laser diode. The method of claim 1, wherein in step (a), The rising edge of the first pulse of the write pulse is synchronized with the rising edge of the mark, the first pulse shifts backward according to the size of the previous space and the current mark, and the last pulse of the write pulse is dependent on the size of the current mark. Adaptive recording method characterized by shifting back and forth to control. The recording method as claimed in claim 2, wherein the recording period is filled with the reproduction light output in the shift period of the rising edge of the first pulse, and the reproduction light output is also filled in the period shifting the falling edge of the last pulse back and forth. Way. 2. The method of claim 1, further comprising the step of re-modifying the waveform of the controlled recording pulse in accordance with a land / groove signal indicating whether the input NRZI data is data of a land track or a groove track. Recording method. The method of claim 1, wherein the controlled write pulse does not take into account the space after the current mark, thereby minimizing time delay. In the method of optimizing and supplying the respective optical powers of the regenerative light output, the peak light output and the bias light output for the recording pulse consisting of the first pulse, the multi-pulse string and the last pulse, to the laser diode: (a) determining a size of a previous space and a size of a current mark of input Non Return to Zero Inversion (NRZI) data; (b) generating pulse width data varying the widths of the first and last pulses of a recording pulse according to the size of the previous space and the size of the current mark; And (c) generating an adaptive recording pulse according to the pulse width data, converting the adaptive recording pulse into a current signal according to the driving level of the optical output of each channel, and applying the same to the laser diode. Adaptive recording method made with. According to claim 6, wherein step (b), (b1) generating first pulse width data for shifting the rising edge of the first pulse of the recording pulse backward synchronized with the rising edge of the mark according to the size of the previous space and the size of the current mark; And (b2) generating second pulse width data shifting back and forth the falling edge of the last pulse of the recording pulse in accordance with the size of the current mark. 8. The adaptive recording method according to claim 7, wherein the regenerative light output is filled in the period in which the rising edge of the first pulse shifts, and the regenerative light output is filled in the period in which the falling edge of the last pulse is shifted back and forth. . 7. The method of claim 6, further comprising: re-modifying the widths of the first and last pulses of the adaptive recording pulse according to the land / groove signal indicating whether the input NRZI data is data of a land track or a groove track. Adaptive recording method further comprises. 7. The adaptive recording method of claim 6, wherein the adaptive recording pulse minimizes time delay since the adaptive recording pulse does not consider the space after the current mark. In a device for controlling the light output of a laser diode: A discriminator for determining the size of the previous space of the input data and the size of the current mark; A generator for generating an adaptive recording pulse by controlling the waveform of the recording pulse according to the size of the previous space and the size of the current mark; And And a current driver for converting the adaptive write pulse into a current signal in accordance with the drive level of the optical output of each channel to drive the laser diode. The method of claim 11, wherein the generator, A recording waveform controller having a memory for storing pulse width data for varying a first pulse width of a recording pulse according to the size of the previous space and the size of a current mark and for varying the width of the last pulse according to the size of the current mark; And And a recording pulse generator for generating an adaptive recording pulse in accordance with the pulse width data. 13. The adaptive recording apparatus according to claim 12, further comprising a microcomputer that initializes the recording waveform controller and controls to update the pulse width data stored in the memory according to a recording condition. 13. The adaptive recording apparatus of claim 12, wherein the memory stores the pulse width data considering whether the input data is land or groove track data. 13. The adaptive recording method according to claim 12, wherein the reproducing optical output is filled in the period during which the rising edge of the first pulse shifts, and the reproducing optical output is filled even in the period in which the falling edge of the last pulse is shifted back and forth. 12. The adaptive recording apparatus of claim 11, wherein the adaptive recording pulse minimizes time delay since the adaptive recording pulse does not consider the space after the current mark.