KR890003587Y1 - Traking erro signal detecting device in optical pickup - Google Patents

Abstract

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Description

Tracking error signal detection device for 3-beam optical pickup

1 is an error signal detection apparatus for tracking of the present invention.

2 is a linear region comparison waveform diagram of the present invention.

* Explanation of symbols for main parts of the drawings

1: subtractor 5: waveform shaper

6: Integrator 8: Comparator I

7: switching circuit 9: comparator II

10: discharge circuit 11: adder

I ₁ , I ₂ : Inverter OR: Oagate

TE: Tracking error signal C ₁ : Capacitor

The present invention relates to a tracking error signal detection apparatus for a three-beam optical pickup with improved linearity of a three-beam optical pickup.

In general, tracking error signal detection is performed by scanning a laser beam onto a disk and then applying reflected light to the photodiode to compare the output of the photodiode receiving the laser beam with each other to detect the tracking error signal. When on and off the track, the reflectance on the disk is different and the output of the photodiode is also different, so it is used to detect the tracking error signal.

However, in the conventional tracking error signal detection method of the three-beam optical pickup, as shown in FIG. 1, the output of the photodiode (e) (f) receiving the auxiliary beam (e ') (f') is subtracted (4). The signal was detected by tracking as a signal subtracted through. However, in this case, there was a drawback that it was difficult to perform high performance tracking due to the narrow linear area.

The present invention is a tracking error signal detection device of a three-beam optical pickup that increases the linear area to detect an improved tracking error signal, and compares the output of the subtractor and the integrator in the comparator I to switch circuits. After passing through, apply to OA gate and compare the output of waveform shaper with the output of discharge circuit in Comparator II. After passing through inverter, input to OA gate, and output of OA gate is applied to integrator through inverter and is applied to discharge circuit. By controlling the operation of the integrator and the discharge circuit, it is configured to detect the tracking error signal through the adder.

This will be described in detail with reference to the accompanying drawings.

1 shows an output A of the subtractor 4 to which the output of the photodiode e, f, which receives the light of the auxiliary beams e 'and f', is applied as the tracking error signal detection apparatus of the present invention. It is configured to be applied to the waveform shaper 5 via the capacitor C ₁ and to the comparator I 8.

In addition, an output B made of square waves in the waveform shaper 5 is applied to the integrator 6 and is applied to the comparator II 9 so that the output C of the integrator 6 is applied to the comparator I 8. It is configured to be applied so that the comparison output (E) of the comparator I (8) is applied to one side of the oragate (OR) after the switching circuit (7).

In addition, the output D of the discharge circuit 10 is applied to the comparator II (9) so that the output (I) to be compared is applied to the other side of the oragate (OR) via the inverter (I ₁ ) so that the oragate (OR) Is applied to the integrator 6 through the inverter I ₂ at the same time as the output G is applied to the discharge circuit 10.

The output of the integrator 6 and the discharge circuit 10 is applied to the adder 11 to output the tracking error signal TE.

According to the present invention configured as described above, the output A of the subtractor 4 to which the output of the photodiode (e) (f) which receives the light of the auxiliary beam (e ') f' is applied is a DC component blocking capacitor ( After C ₁ ), it is applied to the corrugator (5) and the comparator I (8).

At this time, the waveform shaper 5 outputs the square wave according to the slope when the output A of the subtractor 4 passes the zero point of FIG. In this case, the transition of the square wave is in the-direction, and the peak-peak value of the square wave is equal to the peak-peak value of the output A of the subtractor 4.

Therefore, the output B in the waveform shaper 5 becomes a square wave as shown in FIG. 2 and is applied to the comparator II (9) and the integrator 6, and in the integrator 6, the output B of the waveform shaper 5 is integrated. As a result, a linear output C as shown in FIG. 2 is output.

The output C of the integrator 6 is applied to the comparator I 8 so that the comparator I 8 compares the output A of the subtractor 4 and the output C of the integrator 6 to the subtractor. The output (A) of (4) is greater than zero (A> 0) and the output (C) of integrator (6) is greater than zero (C> 0) and the integrator (output (C of 6) is When greater than or equal to the output A (C≥A), the output E of the comparator I 8 is shown to operate the switching circuit 7.

At this time, the switching circuit 7 operates so that the output F of the switching circuit 7 passes through the orate OR, stops the operation of the integrator 6 through the inverter I ₂ , and at the same time, the discharge circuit 10. To output the same output D as in FIG.

Here, as shown in FIG. 2, the discharge circuit 10 has an instant (C> 0) in which the output A of the subtractor 4 is greater than zero (A> 0) and the output C of the integrator 6 is greater than zero (C> 0). A resistor not shown to radiate a signal having the same value as the output A of the subtractor 4 and the output of the integrator 6 to the value of -peak value-(-K) for the same time T as the second degree. The values of (R) and capacitor (C) are determined.

The comparator II (9) compares the output B of the waveform shaper 5 and the output D of the discharge circuit 10 with each other, and outputs the instant (I) at which the output B and the output D become equal to each other. Export

At this time, the output I of the comparator II 9 stops the operation of the discharge circuit 10 through the inverter I ₁ and the OR gate OR and simultaneously operates the integrator 6 through the inverter I ₂ . Let's do it.

Therefore, the integrator 6 and the discharge circuit 10 is always operated without the operation or stop at the same time due to the inverter (I ₁ ) the other side will not operate.

The adder 11 adds the output C of the integrator 6 and the output D of the discharge circuit 10 to detect the desired track error signal TE.

This operation will be described again. The tracking error detection signal obtained by subtracting the output of the photodiode (e) (f) which receives the light of each of the three beams (e ') (f') through the subtractor (4). Is the output signal A from which the direct current component is removed via the capacitor C ₁ , and this output A becomes the output B of the square wave via the waveform shaper 5.

The output B of the square wave becomes a linear output C through the integrator 6, while the comparator I 8 divides the output A of the subtractor 4 and the output C of the integrator 6. In comparison, the output (A) of the subtractor (4) is greater than zero (A> 0) and the output (C) of the integrator (6) is greater than zero (C> 0) and the output (C) of the integrator (6) is the subtractor ( When greater than or equal to the output A of 4) (C≥A), the output E of the comparator I (8) appears to pass through the switching circuit 7 and through the oragate OR and the inverter I ₂ . The discharge circuit 10 is operated at the same time as the operation of the integrator 6 is stopped.

The comparator II (9) compares the output (D) of the discharge circuit (11) and the output (B) of the waveform shaper (5) being discharged, and the output (D) and the waveform shaper (5) of the discharge circuit (11). As soon as the outputs are equal to each other, the output I of the comparator II (9) appears to operate the integrator 6 through the inverter I ₁ and the OR gate and stop the operation of the discharge circuit 10 at the same time. do.

Therefore, the tracking error signal TE is detected by adding the output C of the integrator 6 and the output D of the discharge circuit 10 through the adder 11.

In FIG. 2, the linear region of these signals and the conventional track error signal is compared with the linear region of the tracking error signal detected in the present invention.

As described above, the present invention produces an output C of which the output A of the subtractor 4 becomes a square wave output B through the waveform shaper 5 and increases linearly in the integrator 6.

The comparator I (8) compares the output (A) of the subtractor (4) with the output (C) of the integrator (6) to operate the switching circuit (7) to stop the operation of the integrator (6) and at the same time discharge circuit ( The output D is made by operating 10).

In addition, the comparator II (9) compares the output B of the waveform shaper 5 with the output D of the discharge circuit 10 to operate the integrator 6 and to stop the operation of the discharge circuit 10. By continuously detecting the tracking error signal TE having improved linearity through the adder 11, it is possible to easily perform higher performance tracking by widening the linear area than the conventional tracking error signal. .

Claims (1)

The output A of the subtractor 4 is applied to the waveform shaper 5 and the comparator I 8 through the capacitor C ₁ , and the output B of the waveform shaper 5 is the integrator 6 and the comparator. And the output C of the integrator 6 is applied to the comparator I 8 so that the output E of the comparator I 8 passes through the switching circuit 7 to the oragate OR. After configured to be applied to one side of the output circuit of the discharge circuit 10 is applied to the comparator II (9) is applied so that the output (I) is applied to the other side of the oragate (OR) through the inverter (I ₁ ) The output G of the integrator OR is applied to the integrator 6 through the inverter I ₂ at the same time as the output G of the OR gate OR is applied to the discharge circuit 10 and the discharge circuit 10 and the discharge circuit 10 of the integrator 6. A tracking error signal detection device for a three-beam optical pickup configured to apply an output D) to an adder 11 to generate a tracking error signal JE.