KR20060080621A - Recording power compensation method in accordance with temperature change of writable optical storage - Google Patents

Abstract

The present invention relates to a recording power compensation method according to a temperature change of a recordable optical storage device. When a recording command is performed, a predetermined current is inputted to a laser diode and then the output voltage of the laser diode with respect to the input value is determined. Measuring; Generating and calling a linear equation for automatic power control using the measured predetermined current value and the predetermined output voltage; Executing a new automatic power control operation using the called linear equations; And recording on the optical recording medium.

Light output, laser diode, linear, temperature, optical recording

Description

Recording Power Compensation Method in accordance with Temperature Change of Writable Optical Storage             

1 is a graph illustrating a change in output of a laser diode according to temperature change.

2 is a graph showing slope change of a function showing optical characteristics according to temperature change according to an embodiment of the present invention.

3 is a graph illustrating a change in y-intercept of a function showing optical characteristics according to temperature changes according to an embodiment of the present invention.

4 shows an optical characteristic graph according to actual temperature X according to an embodiment of the present invention.

5 is a flowchart illustrating a recording power compensation method according to a temperature change according to an embodiment of the present invention.

The present invention relates to a recording power compensation method according to a temperature change of a recordable optical storage device, and more particularly, to an algorithm based on linear linear equations for compensating recording power according to a temperature change of a recordable optical storage device.

In a recordable optical storage device (CD / DVD Writer), a control technique for keeping recording power constant is essential. This is called Automatic Power Control (hereinafter referred to as 'APC'), and this technology is more accurate and precise control is being performed by adopting the digital method recently from the conventional analog method.

In other words, APC refers to a technology for controlling a desired power to be accurately emitted from the laser diode LD. However, if the temperature changes due to the physical characteristics of the laser diode, the laser power emitted from the laser diode will change, so the actual laser power output will vary considerably from that of the desired value even if controlled by an accurate APC algorithm. Will be displayed. As a result, patterns recorded by inaccurate recording power contain many errors, which leads to deterioration of reproduction performance due to deterioration of recording quality.

The prior art only performs the write operation according to the write power set at the beginning of the drive design without a method of compensating for the output change of the laser diode due to such temperature change.

In fact, as shown in Figure 1, the laser diode is a laser diode emitted by the physical property generally decreases as the temperature increases. In the figure, the y-axis, which is represented as the output level of the photodiode detector, reflects the laser power emitted from the laser diode and converts the output value into a voltage level. Therefore, the y-axis is generally proportional to the actual laser power of the laser diode. In addition, at the two slopes in the figure, Temp1 displays a characteristic for low temperatures compared to Temp2. In other words. As the temperature increases, the emitted light of the laser diode decreases for the same input value.

The general principle of APC is as follows. Looking at the linear equation for the light output of the laser diode when the temperature is Temp1, when the slope is a and the y-intercept is y1, the linear equation can be expressed as follows.

y = ax + y1 ... (Equation 1)

Here, the photodiode detector output levels P2 and P4 are measured with respect to an arbitrary input value (the input value represents a current value input to the laser diode). Substituting these two points (input values 1, P2) and (input values 2, P4) into Equation 1 above gives the slope a and the y-intercept y1 to obtain the complete linear equation. When the linear information thus obtained is stored in the drive, an accurate photodiode detector output level corresponding to a desired input value, that is, an optical output of a laser diode is obtained.

However, as described above, the laser diode changes in a direction in which the slope of this straight line decreases as the temperature increases. In this case, when the temperature corresponding to Temp2 of FIG. 1 is reached, the input value 1 is obtained to obtain a desired light output P2. Even if it is input, a smaller P4 value is output according to the changed temperature characteristic. It can be seen from the figure that this deviation increases gradually as the input value increases.

The prior art performs the control of the recording power in the same way for Temp2 with only a straight line for Temp1 without any compensation for this.

As a result, as described above, in the case of the recording after the change of temperature inevitably, even if the input value corresponding to the desired recording power is input, the recording power is smaller (at increasing temperature) or larger (at decreasing temperature) than the actual laser diode. It produces the result that comes out. This results in a significantly deteriorated result in recording quality, which causes a fatal defect in reproduction performance.

In other words, the conventional technique does not take into account the amount of change in the light output based on the actual temperature characteristics of the laser diode, so that accurate recording power cannot be controlled, and thus the desired recording power and thus good recording quality cannot be guaranteed.

An object of the present invention has been made to solve the above problems, non-linear to compensate the control error of the recording power caused by simplifying the correlation of the optical output tilt period according to the temperature change, which is a problem of the prior art in a linear straight line It is to provide a method for compensating an ordinary correlation using linear interpolation.

Another object of the present invention is to control the recording power by using digital automatic power control, even if the light output of the laser diode changes with temperature changes, precise control to follow the exact light output corresponding to each input value is carried out To present a new way of doing things.

In order to achieve the above object, in the recording power compensation method according to the temperature change of the recordable optical storage device of the present invention, when a write command is performed, a predetermined current is inputted to the laser diode and the laser diode corresponding to the input value is provided. Measuring the output voltage of the circuit; Generating and calling a linear equation for automatic power control using the measured predetermined current value and the predetermined output voltage; Executing a new automatic power control operation using the called linear equations; And recording on the optical recording medium.

In the present invention, the generating of the linear equation for the automatic power control may include finding the slope (r) using the measured current value and the predetermined output value and using the already generated slope graph, the current temperature (Temp X). ), The y-intercept (yX) corresponding to the temperature is found by using the already generated y-intercept graph, and then it is preferably generated by the formula of y = rx + rX.

In the present invention, the inclination graph generates two linear expressions according to two different temperatures using at least one or more input currents and laser diode output values according to the input currents, and uses the x axis as the temperature axis and the y axis as the tilt axis. It is preferable to generate by.

In the present invention, the y-intercept graph generates two linear equations according to two different temperatures using at least one or more input currents and laser diode output values according to the input currents, and uses the x axis as the temperature axis and the y axis as the y axis. It is preferred to be produced with the intercept axis.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In adding reference numerals to components of the following drawings, it is determined that the same components have the same reference numerals as much as possible even if displayed on different drawings, and it is determined that they may unnecessarily obscure the subject matter of the present invention. Detailed descriptions of well-known functions and configurations will be omitted.

2 and 3 are graphs showing a change in the slope and the y-intercept of the light output characteristic curve according to the temperature change according to an embodiment of the present invention.

In the above embodiment, the graph of FIG. 2 is the axis for the temperature change and the y-axis for the gradient change, and the graph of FIG. 3 is the axis for the temperature change and the y-axis for the y-intercept change.

The above embodiment is a graph showing the change of each parameter according to the temperature change.

Referring to FIGS. 2 and 3, in FIG. 1, each linear equation is obtained for the minimum temperature Temp1 and the maximum temperature Temp2 at which the laser diode operates, as described above.

y = ax + y1 (expression of straight line according to minimum temperature T1) ............. (Equation 1)

y = bx + y2 (expression of straight line for highest temperature T2) ............ (Equation 2)

Given the characteristic value for all temperatures at which the laser diode operates, the slope will be between a and b, and the y-intercept will be between y1 and y2, so the linear equation for any temperature Temp X is You can get it. Assuming that the slopes between the slopes a and b are in a linear relationship, the linear equations of the gradients according to temperature can be expressed as shown in FIG. 2, which is expressed as follows by the two equations obtained above.

y = cx + d ... (Equation 3)

In addition, the relationship between y-intercepts is also expressed by

 y = ex + f ... (Equation 4)

Now, if you store these two straight equations 3 and 4 in the drive, you can enter a current value at any temperature, and then from the photodiode detector output level measured at that time, find a new linear equation for that temperature. Even if the temperature changes, it is possible to control the laser power accurately according to the temperature characteristics.

Figure 4 is a graph showing the actual curve of the light output characteristics formed on the temperature X phase according to an embodiment of the present invention.

Referring to FIG. 4, assuming that the temperature of the current laser diode is Temp X, if the slope at that time is r and the y-intercept is yX, the following equation is obtained.

y = rx + yX ..... (Equation 5)

In the case of a recordable optical storage device, as described above, in order to perform any operation such as reproduction or recording, accurate control of optical output is required, and thus, basic power setting is performed to perform APC. Through this process, a constant reproduction power level and an initial value of the recording power level are obtained. The APC information on the recording power that is held at that time is a problem because the temperature changes.

Therefore, in order to solve this problem, it is necessary to obtain an accurate linear equation 5 suitable for the temperature of the laser diode when the current recording is performed and apply it to obtain a desired light output.

When the write command is dropped, the drive causes a problem when the write operation is performed immediately, using a linear equation corresponding to the existing initial value regardless of the temperature. By simply obtaining a straight line, it can be stored in the drive, allowing precise control to output the recording power at any temperature, which reflects the optical output characteristics of the laser diode.

5 is a flowchart illustrating a recording power compensation method according to a temperature change according to an exemplary embodiment of the present invention.

Referring to Fig. 5, when the write command is dropped, the drive generates a slope and intercept of the straight line 5 obtained by the above-described equation from the photodiode detector output level PX, which is an input value for outputting any input value. Since r and yX can be obtained, the operation of the APC that compensates the light output characteristics of the laser diode for the new current temperature characteristics is performed.

Accurately compensate for this temperature characteristic, the APC algorithm can be effectively used in buffer underrun situations where recording is interrupted and rewritten. In other words, there are various situations such as recording in the middle of aging test (Aging Test) and recording again after checking, or rewriting after stopping recording due to environmental problems during recording. In this case, if the temperature difference between the temperature before the recording stops and the rewriting is large, the recording from the writing point is recorded in a state different from the desired recording power. The quality is significantly reduced.

This causes a lot of difficulties in applying the link technology that exactly two points in the buffer underrun situation, which may lead to playback failure.

In this case, even when the recording is interrupted and rewritten in the middle of the recording, a new linear equation for the current temperature is calculated and acquired through the process of FIG. 5, thereby enabling accurate recording power control.

The present invention reflects the accurate characteristic values for the temperature at that time regardless of the optical output characteristics of the drive at any time, such as when the disc is first recorded or when recording is interrupted. More precise recording power control is performed.

As described above, it has been described with reference to the preferred embodiment of the present invention, but those skilled in the art various modifications and changes of the present invention without departing from the spirit and scope of the present invention described in the claims below I can understand that you can.

As described above, the present invention provides a method that accurately reflects the temperature at each time a write command is transmitted in order to improve the inaccurate light output control caused by the change in the light output characteristic of the laser diode according to the change in temperature. By calculating the optical output characteristic equation and applying it to the drive, accurate recording power control is realized.

In addition, it can be effectively applied to eliminate the problem caused by the temperature difference even in the buffer underrun situation, which is interrupted and rewritten during recording, thereby improving the recording quality and ensuring the stable recording performance and reliability of the drive.

Claims (4)

When a write command is issued, inputting a predetermined current into the laser diode and measuring an output voltage of the laser diode with respect to the input value; Generating and calling a linear equation for automatic power control using the measured predetermined current value and the predetermined output voltage; Executing a new automatic power control operation using the called linear equations; And recording on the optical recording medium. The recording power compensation method according to the temperature change of the recordable optical storage device. The method of claim 1, wherein the generating of the linear equation for the automatic power control comprises: finding a slope r using the measured predetermined current value and the predetermined output value and using a previously generated gradient graph to determine a current temperature. Find (Temp X), find the y-intercept (yX) corresponding to the temperature by using the already generated y-intercept graph, and then generate the equation y = rx + rX. Recording power compensation method according to temperature change of 3. The graph of claim 2, wherein the slope graph generates two linear equations according to two different temperatures using at least one or more input currents and laser diode output values according to the input currents. A record power compensation method according to a temperature change of a recordable optical storage device, characterized in that the axis is generated as the tilt axis. The method of claim 2, wherein the y intercept graph generates two linear equations according to two different temperatures using at least one input current and a laser diode output value according to the input current, and uses the x axis as a temperature axis, A recording power compensation method according to a temperature change of a recordable optical storage device, characterized in that the y-axis is generated by the y-intercept axis.

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