KR0176790B1 - Optical disc play focus pull in circuit - Google Patents

Abstract

The present invention relates to a focus retrieval circuit of an optical disc player. In the conventional circuit, when noise is introduced into the focus error signal, there is a problem in that it is incorrectly determined and malfunctions. The present invention is to solve the conventional problems and to output a control signal for controlling the servo retracting action, and microcontroller for the overall control of the round system for controlling the completion of the servo in accordance with the error comparison signal; An RF amplifier for outputting a focus error signal according to a focus state; An optical disc player comprising a servo inlet circuit unit which controls a focus driving signal according to a control signal of a microcomputer and compares the focus error signal with the first and second reference voltages and transmits an error comparison signal to the microcomputer. When the focus error signal is compared with two reference voltages, the focus induction circuit is designed so that even if noise is introduced, if the noise falls between the two reference voltages, it does not malfunction and stable servo in. There is an effect that can work.

Description

Focus lead circuit of optical disc player

1 is a block diagram of a focus lead circuit of a conventional compact disc player.

2 is a timing diagram of each signal in FIG.

3 is an output waveform diagram of a focus error signal and a focus ok signal in the case where there is noise in FIG.

4 is a block diagram of an embodiment of a focus lead-in circuit of the optical disc player of the present invention.

5 is a timing diagram of each signal in FIG.

* Explanation of symbols for main parts of the drawings

100: microcomputer 200: serial / parallel conversion unit

300: RF amplifier 400: servo in circuit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical disc player. In particular, when the focus error signal is compared with the reference signal in the servo in circuit section of the focus inlet circuit, the comparison error signal is compared with the two levels of the reference signal so that a stable comparison signal is obtained even if noise is included in the focus error signal. It relates to a focus lead circuit of an optical disc player to be suitable for outputting

FIG. 1 is a block diagram of a focus lead circuit of a conventional optical disc player. As shown in FIG. 1, the microcomputer 100 collectively controls the system by outputting control signals XLAT, MCLK, and SDATA for controlling the servo lead. Wow; A serial / parallel converter 200 for converting and outputting serial control signals XLAT, MCLK, and SDATA output from the microcomputer 100 into parallel control signals XLTO and PDATA; An RF amplifier 300 for outputting a focus ok FOK or a focus error signal FE; In response to the control signals XLTO and PDATA of the serial / parallel converter 200 and the output signals FOK and FR of the RF amplifier 300, a focus error signal FODV is output and a focus error signal ( The servo input circuit unit 400 compares the FE with a reference value and transmits the error comparison signal FZC to the microcomputer 100.

The operation of the conventional circuit configured as described above will be described with reference to FIGS. 2 and 3.

The focus inlet circuit is a circuit for focusing the disk during initial operation. First, when the microcomputer 100 outputs the serial control signals XLAT, MCLK, and SDATA for controlling the servo inlet action, the serial / parallel converter 200 converts it into parallel control signals XLTO and PDATA and applies it to the servo in circuit 400.

In this case, the RF amplifier 300 applies a focus ok signal FOK and a focus error signal FE to the servo in circuit 400.

Accordingly, the servo in circuit 400 controls the focus driving signal FODV according to the output signal of the serial / parallel converter 200, and compares the focus error signal FE with a reference offset voltage Voff1. The error comparison signal FZC is transmitted to the microcomputer 100.

The microcomputer 100 receiving the error comparison signal FZC from the servo inlet circuit unit 400 is configured to complete the servo induction operation when the error comparison signal FZC becomes 'high' and then changes to 'low' again. Take control.

For example, if the data signal PDATA through the microcomputer 100 is the focus down signal '02' as shown at point B of FIG. 2A, it is shown in FIG. 2B. The servo in circuit 400 receiving the latch signal XLTO reduces the focus driving signal FODLV as shown in FIG.

Since the focus ok signal FOK output from the RF amplifier 300 is not yet a focus ok, the focus ok signal FOK is in a 'low' state as shown in (d) of FIG. 2, and the focus error signal FE is the servo lead circuit unit 400. In comparison with the reference offset voltage (Voff1), it is less than the reference offset voltage (Voff1) is also a 'low' state as shown in (e) of FIG.

If the focus error signal FE is smaller than the reference offset voltage Voff1 as described above, the error comparison signal FZC also becomes a 'low' state as shown in FIG. If the focus error signal FE is greater than the reference offset voltage Voff1, the signal becomes a 'high' signal.

At this time, if the control signal PDATA through the microcomputer 100 is the focus up signal '03', the servo in circuit 400 increases the focus driving signal FODV as shown in FIG. .

During this operation, the focus ok signal FOK output from the RF amplifier 300 becomes 'high' as in the stage CD of FIG. 2 and the focus error signal FE as in point D of FIG. Is larger than the reference offset voltage Voff1, the error comparison signal FZC also becomes 'high' as shown in (f) of FIG.

Thereafter, when the focus error signal FE becomes smaller than the reference offset voltage Voff1 again, as in point E of FIG. 2, the error comparison signal FZC becomes 'low' again, and at this time, the microcomputer 100 The '08' signal, which is a focus on signal, is applied to the servo in circuit 400.

Accordingly, the servo retraction operation is completed.

However, when the noise flows into the focus error signal FE and becomes larger and smaller than the reference offset voltage Voff1 temporarily as in the section AB of FIG. 3E, the servo input circuit 400 converts the signal into a comparison result signal. As shown in (f) of FIG. 3, the output error comparison signal FZC temporarily generates square wave pulses.

As a result, the microcomputer 100 determines that the servo retracting operation is completed before the normal error comparison signal FZC is applied as shown in the section C-D of FIG. 3 and outputs the focus-on signal.

As described above, in the conventional circuit, when noise is introduced into the focus error signal, there is a problem of incorrectly determining the malfunction.

An object of the present invention is to compare the focus error signal with the two reference voltages in order to solve the conventional problems, so that the optical disc player can be stably servo-in operation even when noise is introduced into the focus error signal. In order to provide the focus of the circuit.

In order to achieve the object of the present invention, a focus retrieval circuit of an optical disc player outputs a control signal for controlling a servo retraction action, and controls a servo retrieval completion according to an error comparison signal. ; An RF amplifier for outputting a focus error signal according to a focus state; The servo drive circuit controls the focus driving signal according to the control signal of the microcomputer and compares the focus error signal with two reference voltages and transmits the error comparison signal to the microcomputer.

One embodiment of the present invention will be described.

4 is a block diagram of an embodiment of a focus retrieval circuit of an optical disc player according to the present invention. As shown in FIG. 4, a microcontroller for collectively controlling a system such as outputting control signals XLAT, MCLK, and SDATA for controlling servo retraction Computer 100; A serial / parallel conversion unit 200 which receives the control signals XLAT, MCLK, and DATA output from the microcomputer 100 and converts them into corresponding signals XLTO and parallel data signals PDATA; An RF amplifier 300 for outputting a focus error signal FE according to a focus state; The focus drive signal FODRV is controlled according to the control signals XLTO and PDATA of the serial / parallel converter 200, and the focus error signal FE is compared with two reference offset voltages Voff1 and Voff2. As a result, the servo comparison circuit 400 outputs the error comparison signal FZC to the microcomputer 100.

When described in detail with reference to the accompanying Figure 5 with respect to the effect of the present invention through the action of one embodiment of the present invention configured as described above are as follows.

The overall operation is the same as before. That is, the microcomputer 100 outputs the latch signal XLAT, the master clock signal MCLK, and the serial data signal SDATA for controlling the servo retraction operation.

Accordingly, the serial / parallel conversion unit 200 receives the output signal of the microcomputer 100, outputs the latch signal XLTO to the servo in circuit 400, and converts the serial data signal SDATA in parallel. Output the signal PDATA.

Meanwhile, the RF amplifier 300 outputs the focus error signal FE according to the focus state to the servo in circuit 400, and thus the servo in circuit 400 outputs the focus error signal FE. Compared to the two reference offset voltages Voff1 Voff2, the error comparison signal FZC is transmitted to the microcomputer 100.

At this time, if the focus error signal FE is greater than the first reference offset voltage Voff1, an error comparison signal FZC that is 'high' is output. If the focus error signal FE is less than the second reference offset voltage Voff2, an error comparison is 'low'. Output the signal FZC.

The focus driving signal FODLV is controlled according to the output data signal PDATA of the serial / parallel converter 200.

For example, as in the point F of FIG. 5, the data signal PDATA in the initial state is '00' which means focus off. In this case, since the focus error signal FE is not detected, the error comparison signal FZC is also not generated. The focus driving signal FORDR stays at the reference voltage Vr.

Thereafter, when the data signal '05' representing the focus search is input, the signal is temporarily latched by the latch signal XLTO as shown in FIG. Delivered.

Accordingly, as shown in (c) of FIG. 5, the servo lead-in circuit unit 400 decreases the focus driving signal FODDR by a predetermined time T and increases it again.

During this process, the microcomputer 100 applies the data signal 08 representing the focus-on to the servo in circuit 400.

At this time, when the focus error signal FE output from the RF amplifier 300 becomes larger than the first reference offset voltage Voff1 as shown at point H in FIG. Output error comparison signal FZC.

Thereafter, when the focus error signal FE is smaller than the second reference offset voltage Voff2, the servo in circuit 400 outputs an error comparison signal FZC that is 'low'.

The microcomputer 100 receiving the error comparison signal FZC of the servo in circuit 400 determines that the servo in action is completed and outputs the latch signal XLAT accordingly.

The latch signal XLAT is applied to the servo input circuit unit 400 as a latch signal XLTO as shown in FIG. 5B through the serial / parallel conversion unit 200.

Accordingly, the servo in circuit 400 stops the control of the focus driving signal FORDR.

At this time, even if noise is introduced into the focus error signal FE, if the noise is between two reference offset voltages Voff1-Voff2, the noise is not affected.

As described in detail above, when comparing the focus error signal, the present invention compares the two reference voltages so that even if noise is introduced, if the noise falls between the two reference voltages, it does not malfunction so that stable servo induction can be performed. It can be effective.

Claims (2)

A microcomputer for totally controlling the system, such as outputting a control signal for controlling the servo inlet action and controlling the completion of the servo inlet according to the error comparison signal; An RF amplifier for outputting a focus error signal according to a focus state; The servo drive circuit controls the focus drive signal according to the control signal of the microcomputer and compares the focus error signal with the first and second reference voltages and transmits the error comparison signal to the microcomputer. Focus lead-in circuit of an optical disc player. The focus-in circuit of claim 1, wherein the first reference voltage is 1.0V and the second reference voltage is 0.5V.