KR20080060466A - Setting method of laser power in optical disc driver - Google Patents

Abstract

A method of setting laser power in an optical disk device is provided to calculate accurate output power gradient of a laser diode by applying the offset resulting from temperature of the pickup to reflect power features of the laser diode. A method of setting laser power in an optical disk device comprises the steps of: measuring laser input voltage with respect to two input values(S20); calculating gradient of input voltage by using the two measured input voltages(S21); calculating output power gradient by substituting the input voltage gradient to a specific formula(S23); and storing the output power gradient calculation formula(S24).

Description

Setting method of laser power in optical disc driver

1 is a control block diagram for setting a laser power of the optical disk apparatus according to the present invention,

2 and 3 show an operation flowchart for setting the laser power of the optical disk apparatus according to the present invention,

4 shows a characteristic diagram at the time of laser power setting in the optical disk apparatus according to the present invention.

Explanation of symbols on the main parts of the drawings

10: optical disc 11: spindle motor

20: optical pickup 40: channel bit encoder

41: optical drive 50: R / F section

60: drive portion 61: servo portion

70: Micom 71: EEPROM

30a: digital recording signal processor 30b: digital reproduction signal processor

80: level detector 85: AGC

The present invention relates to a laser power setting method for an optical disk device, and more particularly, to a laser power setting method for an optical disk device for finding the slope of an output power accurately and at high speed in relation to an input voltage.

The optical disc apparatus requires laser power of various sizes in accordance with other operating states such as recording or reproduction. Typically, the laser power detects and stores power curve data necessary for laser power setting by performing a laser power setting operation for each optical disk device in a manufacturing process step of the optical disk device.

For this purpose, since the ratio of the correct output power to the input voltage is not known due to the mechanical and optical characteristics of the optical pickup, the regression equation is derived by applying the statistical characteristics to use the characteristic equation. In order to obtain the characteristic equation, the FMD (Front Monitor Diode) value which receives the laser beam output from the pickup and passes through the analog / digital converter, the DSP input value input for the laser output of the pickup, and the DSP input value are the optical disk device. Variables such as voltage values actually passed through the various hardware devices in the pickup's lasers are needed.

Since statistical properties are applied to implement characteristic equations using the variable values, a method of calculating power from characteristic equations obtained from these values by measuring 10 or more sample data for each set in 50 or more sets, have.

Therefore, in order to obtain a characteristic equation for calculating the laser power of the optical pickup in the conventional optical disk device, a method of calculating from 10 or more sample data per set from at least 50 sets or more is employed, which requires a lot of time and effort. I have a feeling.

In addition, the conventional optical disk device measures a value (FMD value, DSP input value, voltage value) to be monitored from several sets in order to obtain sample data from the characteristic equation, but the measured values have a predetermined offset value. It is included. Since the offset value does not always maintain the same value due to the temperature characteristic of the pickup, the offset change is included in the sample data. Therefore, in the conventional optical disk device, there is a problem that the laser power is set by increasing the error range of the characteristic equation from the offset value.

Therefore, the present invention was created to solve the above problems, and the laser power setting method of the optical disk device that can remove the influence of the offset by the temperature by deriving the laser power gradient from the voltage value actually applied to the optical pickup The purpose is to provide.

A laser power setting method of an optical disk apparatus according to the present invention for achieving the above object comprises the steps of: measuring a laser input voltage for any two input values; Calculating a slope of an input voltage using the measured two input voltages; And a third step of calculating an output power slope by using an output power slope calculation formula relative to a slope of a predetermined input voltage.

The present invention is characterized in that it further comprises a fourth step of calculating the laser output power by applying the output power slope calculated in the third step to a predetermined power calculation formula.

The predetermined power calculation equation of the fourth step of the present invention is characterized in that the output power slope, the input value, and an offset value for the input value are applied as variables.

The predetermined output power gradient calculation formula of the third step of the present invention obtains the slope of the laser input voltage for two input values, the slope of the laser output voltage for two input values, and obtains from the two slope relations. In particular, the present invention is characterized in that it further comprises the step of storing the predetermined output power gradient calculation formula of the third step.

Hereinafter, a preferred embodiment of a laser power setting method of an optical disk apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

1 shows an overall configuration diagram of an optical disk apparatus according to the present invention.

As shown in the drawing, the optical disk apparatus of the present invention includes a digital recording signal processing unit 30a for adding an error correction code (ECC) or the like to input digital data to convert it into a recording format, and converting the data converted into the recording format. And a channel bit encoder 40 for reconverting to a bit stream, and an optical driver 41 for outputting a light quantity driving signal according to the input signal.

In addition, the optical disk apparatus of the present invention includes an optical pickup 20 for recording a signal on the optical disk 10 in accordance with the light amount driving signal, and detecting a recording signal from a recording surface, and a signal detected by the optical pickup 20. R / F unit 50 for outputting a binary signal by shaping the filter, a drive unit 60 for driving the optical pickup 50 and the spindle motor 11, and a tracking error signal of the optical pickup 20 (TE) and a focusing error signal (FE) and a servo unit 61 for controlling the drive of the drive unit 60 from the rotational speed of the optical disc 10.

The optical pickup 20 may include a laser diode LD for generating a laser based on a light amount driving signal output from the optical driver 41, and a signal for reflecting the laser generated by the laser diode from the disk 10. Receiving photo diode (PD), Front monitor diode for receiving the light emitted from the laser diode as it is and generates an output signal (Front Moniter Diode Output; FMD) for checking the amount of light emitted (light intensity) of the laser diode, Other configuration, such as an objective lens for guiding the light to the disk 110, but the configuration of the optical pickup 120 is the same as the general configuration, detailed description thereof will be omitted.

The optical disk apparatus of the present invention includes a digital reproduction signal processing unit 30b for restoring the binary signal to original data with its own clock synchronized with the binary signal, and a memory in which laser power, which will be described later, is stored in the form of firmware. 71 and a microcomputer 70 for setting the power of the laser diode.

The memory 71 stores characteristic equations for calculating the power value of the laser diode output using the voltage value DRV actually provided to the laser diode in the optical pickup for the input DAC input value. In addition, the constant values α and β set based on the plurality of sets of experimental values are stored. Values stored in the memory 71 will be described in detail later.

In addition, the present invention comprises a level detector 80 for detecting the level of the voltage signal output from the optical driver 41, the level value detected by the level detector 80 is a detection value for setting the laser power Used as The laser output power value detected by the FMD is configured to be converted into a digital signal. In this embodiment, the analog-to-digital converter included in the DSP 30b is used. The AGC 85 compensates for the gain of the reproduction signal output from the RF unit 50.

The laser power setting method of the optical disk device of the present invention having the above-described configuration uses the result value of the voltage value actually input to the laser diode of the optical pickup for the two DAC input values, thereby increasing the voltage characteristic. The laser power is obtained by changing the power increase rate, and the operation is performed as follows.

First, the present invention performs the following operation to obtain a relation between the slope of the voltage value (hereinafter referred to as the input voltage value) actually input to the laser diode and the slope of the output value of the laser power (hereinafter referred to as laser power). .

2 is an operation flowchart for obtaining a relationship between the input voltage value and the laser power according to the present invention.

First, sample data is obtained for two input DAC values for each set from about 30 optical disk devices. The procedure of repeatedly obtaining sample data for each of the two input DAC values obtained from the 30 sets from the process of FIG. 2 is repeated.

That is, the optical driver 41 outputs each laser diode input voltage value with respect to two DAC input values (for example, 0, 1) input through the microcomputer 70. The output of the optical driver 41 is applied to the laser diode in the optical pickup 20 to be a value for generating an optical signal, thereby generating light emission of the laser diode.

At this time, the laser diode input voltage value output from the optical driver 41 is detected through the level detector 80 to the level of the input voltage value (S10).

Next, the intensity of light emitted from the laser diode is received through the front monitor diode FMD, and the received optical signal is detected as an output power value of the laser diode (S11).

The power value of the laser diode is converted into a digital signal through an analog / digital converter. The analog-to-digital converter may be provided separately or may be performed through the DSP 30b.

The laser diode input voltage value DRV detected in step S10 and the laser diode power value PWR detected in step S11 are input to the microcomputer 70. The microcomputer 70 calculates the slope l1 using the two input voltage values of the two DAC input values detected in the step S10 (S12). In addition, the microcomputer 70 calculates a slope l2 using two power values for the two input voltage values detected in the step S11 (S13). The calculation method of the two inclinations l1 and l2 uses a general linear equation to obtain the inclination using values for two points.

Then, the microcomputer 70 derives the first-order curve graph shown in FIG. 4 using the inclination value obtained in the step S12 and the inclination value obtained in the step S13 (S14). That is, in the linear curve graph, the X axis represents the slope of the input voltage value with respect to the DAC input value, and the Y axis represents the slope of the power value with respect to the DAC input value. In FIG. 4, the DAC input value represents an analog value with respect to the digital input value for setting the laser power. Therefore, the DAC input value may be a value passed through a digital-to-analog converter in the DSP.

Looking at the relationship between the two slopes from the above relation, it can be seen that the increase of the input voltage value is represented by the increase of the actual output power value. Therefore, to summarize this, the first-order linear function obtained in step S14,

It is obtained by PWR_SLOPE = α * DRV_SLOPE + β.

Since the slope of the input voltage DRV_SLOPE and the slope of the output power PWR_SLOPE are known from the first-order linear function for the sample data obtained from at least 30 sets thus obtained, it is necessary to determine the power increase with respect to the increase of the input voltage value. It is possible to obtain constant values α and β. Therefore, the linear linear function whose constant value is determined is stored in the memory 71.

Next, a process of obtaining a power value of a laser diode in each optical disk device by using the first linear function obtained as described above will be described.

3 is an operation flowchart for setting laser power in the optical disk apparatus according to the present invention.

A process for determining laser diode output power in each set is performed in a state in which a linear linearity function whose slope of an output power value is determined in response to a slope of an input voltage value determined in step S14 is stored in the memory 71. It is done.

First, in order to determine the laser diode output power in the optical disk apparatus, the DAC values for any two points are provided. The two DAC values are converted into analog signals and applied to the optical driver 41, which generates a laser diode input voltage value corresponding to the values. The input voltage value DRV of the laser diode for the two DAC values thus generated is provided to the laser diode in the optical pickup 20 so that the laser diode emits the laser as much.

At this time, the level detector 80 detects the voltage value generated by the optical driver 41 and outputs a level value proportional thereto.

The level value detected in step S20 is input to the microcomputer 70, and the microcomputer 70 calculates the slope l1 using two level values of two DAC values (S21).

The microcomputer 70 calculates a power value slope PWR_SLOPE using the slope value l1 obtained in the step S21 using the first-order linear function stored in the memory 71 (S22).

The relation between the power slope value and the DAC value is derived using the power slope value obtained in the step S22 (S23). The power gradient coefficient is stored in the memory 71 from the relational expression (S24).

The value stored in the memory 71 in the step S24 is a coefficient value applied when determining the laser diode power value in the current optical disk device.

Therefore, when the laser diode power value is determined later in the optical disk apparatus, the power gradient value, the DAC value, and the offset value of the DAC value are applied to determine the final laser diode power value (S25).

Here, the DAC offset value represents an offset of the D / A converter generated in the process of converting an applied DAC value (0, 1) into an analog signal. For example, the DAC offset can be detected using the slope formula of the linear equation determined by any two input voltages and the laser power output therefrom.

The above-described preferred embodiment of the present invention is disclosed for the purpose of illustration, and may be applied to determine the output power of the laser power by obtaining the increase of the output power with respect to the increase of the input voltage. Therefore, those skilled in the art will be able to improve, change, substitute or add other embodiments within the technical spirit and scope of the present invention disclosed in the appended claims.

Optical disk according to the present invention described above The laser power setting method of the optical disk apparatus according to the present invention is characterized by calculating the slope of the output power of the laser diode using the slope of the input voltage. According to this feature, the present invention has an effect of obtaining a more accurate power gradient by reflecting the power characteristics of the laser diode in consideration of the offset due to the temperature and other influences of the pickup. In addition, the present invention is a very useful invention that can be obtained with the effect of reducing the power setting time because the power gradient is determined using the sample data for about two points compared to the conventional.

Claims (5)

Measuring a laser input voltage for any two input values; Calculating a slope of an input voltage using the measured two input voltages; And a third step of calculating an output power gradient by using an output power gradient calculation formula relative to a predetermined slope of an input voltage. The method of claim 1, And a fourth step of calculating a laser output power by applying the output power slope calculated in the third step to a predetermined power calculation equation. The method of claim 2, In the predetermined power calculation formula of the fourth step, an output power gradient, an input value, and an offset value with respect to the input value are applied as variables. The method of claim 1, The predetermined output power gradient calculation formula of the third step is obtained by obtaining the slope of the laser input voltage with respect to the two input values and the slope of the laser output voltage with respect to the two input values, and obtaining from the two slope relational expressions. Laser power setting method of optical disk device. The method of claim 4, wherein And storing the predetermined output power gradient calculation formula of the third step.

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