KR0121392Y1 - Side beam ballance automatic controller for optical disk system - Google Patents

Abstract

The present invention relates to an optical disc system, and more particularly, to an apparatus for automatically adjusting side beam balance of an optical disc system that enables automatic adjustment of side beam unbalance.

The conventional EF adjustment method has a disadvantage in that the adjustment time is longer to adjust the EF balance by manipulating the up / down switch after the controller observes the tracking error signal through the oscilloscope. There was a problem that it is impossible to adjust the correct EF balance.

Therefore, the present invention compares the integration means for integrating the detected tracking error signal with the integral value obtained from the integration means and a predetermined reference level, and controls the resistance value of the electronic variable resistance as a result to adjust the side beam balance. Comparing and controlling means for automatic adjustment have solved all the problems of the prior art as described above.

Description

Automatic adjustment of side beam balance of optical disc system

1 is an explanatory diagram of an optical spot (SPOT) of a general tracking servo.

2 is a side beam balance adjustment circuit diagram of a conventional optical disc system.

(A) to (d) of FIG. 3 are tracking error waveform diagrams.

(a) is a tracking error waveform diagram in a steady state,

(b) to (d) are tracking error waveform diagrams when the side beam is biased.

4 is a block diagram of the automatic adjustment of the side beam balance of the optical disk system according to the present invention.

5 is a relationship between the tracking error signal and the output signal of the integrator.

* Explanation of symbols for main parts of the drawings

2: operational amplifier 4: Y pyrom

5: integral part 6: comparison and control unit

The present invention relates to an optical disc system, and more particularly, to an apparatus for automatically adjusting side beam balance of an optical disc system that enables automatic adjustment of side beam unbalance.

In general, in the optical disc system, the optical spot SPOT of the three-beam tracking servo is composed of a main main beam M and two side beams E and F, as shown in FIG.

The tracking error signal (hereinafter referred to as T.E signal), which is a signal for controlling the tracking servo, is a signal obtained by subtracting F, the second side beam light receiving signal, from E, which is the light receiving signal of the first side beam.

In this case, the E signal, which is the first side beam 1 light receiving signal, and the F signal, which is the second side beam light receiving signal, differ from device to device according to the characteristics of the light receiving diode as the light receiving unit.

Therefore, the error of the received signal should be corrected, which is referred to as E-F balance adjustment (or side beam balance adjustment).

In the conventional optical disc system, as shown in FIG. 2, the apparatus for adjusting the side beam balance includes first and second voltage divider resistors R1 and R2 for dividing the first light receiving signal E, and a second light receiving signal. The voltage divided by the electron variable resistor 1 and the second voltage divider R3 (and the first and second voltage divider resistors R1 and R2) for dividing F), and the electron variable resistors 1 and 3 Operational amplifier (2) for amplifying the difference voltage with voltage divided by voltage divider (R3) and outputting it as TE signal, and up / down switch (SW1) (SW2) for inputting a signal for adjusting side beam unbalance And a control unit 3 for adjusting the electronic variable resistance 1 by outputting an EF balance correction signal according to the on / off of the up / down switches SW1 and SW2, and the EF obtained by the control unit 3. It consists of two pyrom (4) for storing the correction value.

The operation of the apparatus for adjusting the side beam balance of the conventional optical disk system configured as described above will be described with reference to FIG. 3.

First, the first light receiving signal E, which is the first side beam, is divided into first and second voltage divider resistors R1 and R2 and input to the non-inverting terminal + of the operational amplifier 2.

In addition, the second light receiving signal F, which is the second side beam, is divided into the electronic variable resistor 1 and the third voltage divider R3 and input to the inverting terminal (−) of the operational amplifier 2 described above.

The operational amplifier 2 subtracts the voltages respectively input to the non-inverting terminal (+) and the inverting terminal (-) in this way, amplifies the difference voltage and outputs the T.E signal to enable the tracking servo at the rear end.

On the other hand, when tracking servo is performed during E-F adjustment, the tracking error signal becomes as shown in FIG. 3 (d) and becomes almost the same as the reference level, making it difficult to adjust the E-F balance.

Therefore, during the E-F adjustment, the tracking servo is stopped so that the tracking error signal as shown in FIGS. 3A to 3C can be obtained by the eccentricity while the disk is rotating.

On the other hand, the EF coordinator observes the tracking error signal (TE signal) obtained through the operational amplifier 2 as described above with an oscilloscope and accordingly to the error, the up / down switch so that the TE signal is as shown in FIG. You can manually adjust the EF balance by operating (SW1) (SW2).

That is, when the up / down switch SW1 (SW2) is pressed by the adjuster, the controller 3 increases the resistance value of the electronic variable resistor 1 in correspondence with the input of the up / down switch SW1 (SW2). EF is adjusted by decreasing the partial pressure ratio of the second light receiving signal F.

Thus, when the adjustment of the E-F is completed, the controller 3 stores the optimum E-F adjustment value (that is, the electronic variable resistance adjustment value) in the Y pyrom 4 to be utilized in the next control.

However, the conventional EF adjustment method has a disadvantage in that the adjustment time becomes longer for the adjuster to adjust the EF balance by manipulating the up / down switch after observing the tracking error signal through the oscilloscope. There was a problem that it is impossible to adjust the EF balance accurately because of manual operation.

Accordingly, the present invention is to solve the above-mentioned problems of the prior art, and an object of the present invention is to integrate the tracking error signal detected and compare the integral value with the reference value to automatically adjust the side beam balance of the optical disc system. It is to provide a side beam balance automatic adjustment device.

Technical means for achieving the object of the present invention is an integration means for integrating a tracking error signal obtained by comparing the first side beam received signal and the second side beam received signal, the integral value obtained from the integration means and the predetermined value Comparison and control means for comparing the reference adjustment value and controlling the resistance value of the electronic variable resistance by the difference value to automatically adjust the side beam balance.

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

4 is a block diagram of the automatic adjustment of the side beam balance of the optical disk system of the present invention. The first and second voltage divider resistors R1 and R2 for dividing the first light receiving signal E and the second light receiving signal F are shown in FIG. The electronic variable resistor (1) and the third divided resistor (R3) for dividing the voltage, the voltage divided by the first and second divided resistors (R1) (R2) and the electronic variable resistor (1) and the third divided resistor An arithmetic unit 2 which amplifies the difference voltage with the voltage divided by R3 and outputs the TE signal as an TE signal, and an integrating unit which integrates and outputs a tracking error signal (TE signal) output from the arithmetic amplifier 2 ( 5) and comparing the integral value output from the integrating unit 5 with a preset reference adjustment value, and adjusting the balance of the side beam by changing the resistance value of the electronic variable resistor 1 according to the result. And an Y pyrom 4 for storing the comparison and the EF correction values obtained by the control unit 6.

Referring to Figure 5 attached to the effect of the automatic adjustment of the side beam balance of the optical disk system according to the present invention configured as described above is as follows.

First, the first light receiving signal E, which is the first side beam, is divided into first and second voltage divider resistors R1 and R2 and input to the non-inverting terminal + of the operational amplifier 2.

In addition, the second light receiving signal F, which is the second side beam, is divided into the electronic variable resistor 1 and the third voltage divider R3 and input to the inverting terminal (−) of the operational amplifier 2 described above.

The operational amplifier 2 subtracts the voltages input to the non-inverting terminal (+) and the inverting terminal (-) in this way, amplifies the difference voltage to a predetermined level and outputs it as a tracking error signal (TE signal). Enable tracking servos.

On the other hand, in order to adjust the side beam balance, the integrating unit 5 integrates the tracking error signal (TE signal) obtained from the operational amplifier 2 into the integrator 5a, and compares and compares the analog / digital conversion port in the control unit 6. Input it to (A / D).

When the tracking error signal is the same as (a) of FIG. 5, the integrating unit 5 inputs the integral value of the waveform such as a of FIG. 5 (b) to the comparison and control unit 6.

Accordingly, the comparison and control unit 6 compares the digital tracking error signal input through the analog / digital conversion port A / D with a preset reference level.

The preset reference level is integrated in the tracking error signal of the steady state as shown in (a) of FIG. 3 through an integrator and stored in the ypyrom 4 as a waveform value as shown in FIG. 5 (b).

Therefore, the comparison and control section 6 compares the reference level as described above with the integral value obtained in the integrating section 5, and as a result, calculates the E-F balance correction value.

When the EF balance correction value is calculated as described above, the control signal for the EF balance correction is output through the control port P1 to adjust the resistance value of the electronic variable resistor 1, thereby reducing the partial pressure ratio of the second light receiving signal F. By adjusting, you adjust the EF balance.

In addition, the comparison and control unit 6 stores the E-F balance correction value calculated as described above in the ypyrom 4 to be used for the next control.

As described in detail above, the present invention has an effect of shortening the adjustment time of the E-F balance because the adjustment of the E-F balance is possible automatically, and also has the effect of ensuring accuracy by automatically adjusting the E-F balance.

Claims (1)

An apparatus for adjusting a side beam balance of an optical disk system, comprising: an integrating unit for integrating a tracking control signal obtained by comparing a first side beam and a second side beam, and an integral value obtained in the integrating unit with a preset reference value; A device for automatically adjusting the side beam balance of an optical disc system, comprising a comparison and control unit for adjusting the resistance value of the electronic variable resistance according to the value.