KR940003665B1 - Signal control circuit - Google Patents

Abstract

This circuit prevents the error of mirror signal by regulating the input of radio frequency (RF) signal from a pick-up at high speed searching for information on a disk. The circuit comprises; a capacitor which connects the 1st output sec. and the 2nd output sec. and bypasses the alternating component of RF signal transmitted from the 1st input sec.; a resisting means (30) which attenuates the input of RF signal; a regulating means which regulates the resistance value according to the 1st and 2nd operating mode of an optical record regeneration device.

Description

Signal conditioning circuit

1 is a conventional mirror signal generation circuit diagram.

2 is a waveform diagram of each part in the normal speed search according to FIG.

3 is a waveform diagram of each part in the high-speed search according to FIG.

4 is a signal control circuit diagram according to the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a signal control circuit of an optical recording / reproducing apparatus such as a compact disk-ROM (CD-ROM). In particular, a mirror signal is controlled by adjusting an input of an RF signal applied from a pickup when high-speed search of information on a disk The signal control circuit of the optical recording and reproducing apparatus for preventing the error of the.

Typical optical recording and reproducing apparatuses seek optical transmission servos for moving the optical pickup body in the outer or inner circumferential direction on the optical disk.

Since the optical system sending servo is a servo for moving a sled motor, it is commonly called a sled servo.

Such a sled servo moves the sled motor in response to a command of a control system such as a microcomputer, so that the optical pickup main body linearly moves in the outer or inner circumferential direction on the optical disk.

Therefore, the sled servo is very useful for high speed search of a large amount of information recorded on the optical disk.

Typically, the RF signal read from the optical pickup is converted into an analog high frequency signal on the disk.

The RF signal is often amplified by a high frequency amplifier and input to a mirror circuit which performs bottom hold and peak hold.

The mirror circuit is a circuit for generating a mirror signal from the RF signal, and is usually embedded in a large scale integrated chip (LSI). The mirror signal is a signal containing information about the track of the disc, which is an important signal that allows the servo to generate track counting data.

1 is a conventional mirror signal generation circuit diagram, in which a "CXA 1081M" LSI chip manufactured by Sony, which is widely used now, is incorporated.

A mirror signal generation circuit 100 of the related art will be described with reference to FIG.

In FIG. 1, the RF signal applied to the first input terminal RF− is output to the first output terminal RFO through a summing amplifier 1.

The summing amplifier 1 is an amplifier usually included in the RF amplifier, and is an amplifier that sums the outputs of two RF 1-V amplifiers located in front of the summing amplifier 1.

The normal signal waveform appearing at the first output stage RFO is the same as the second waveform RFO.

In the waveform, the RFO is coupled to the DC component of the RF signal by a capacitor C1 connected to the first output terminal RFO, and only the AC component is passed through the mirror amplifier 2 through the second input terminal RFI. Is input to the inverting end of (-).

Therefore, the mirror amplifier 2 inverts and amplifies only the AC component of the waveform RFO and applies it to the output terminal G.

Here, the signal waveform of the output terminal G is shown as the waveform G of FIG.

The waveform G is applied to the hold portion 3 to be bottom held and peak held.

That is, the hold unit 3 detects only the peak waveform of the waveform G and the envelope waveform at the bottom and applies them to the amplifier 4 through the lines H and I.

Therefore, the amplifier 4 amplifies and applies the held waveform G to the output terminal (J).

Here, the held waveform G appearing at the output terminal J is the same as the waveform J in FIG.

The waveform J is applied to the non-inverting terminal (+) of the first amplifier OP1, which is a mirror hold amplifier, through the resistor R2 and to the inverting terminal (-) of the second amplifier OP2, which is a mirror comparator.

The output of the first amplifier OP1 is for setting the comparison reference level on the line K connected between the diode and the capacitor C2.

Accordingly, the second amplifier OP2 compares the waveform reference point and the comparison reference level appearing on the line K and outputs a mirror signal to the output terminal MIRR.

The reference level on the line K is the same as the waveform K shown by the dotted line in FIG. 2, and the mirror signal of the output terminal MIRR is the same as the waveform MIRR.

In FIG. 2, it can be seen that the mirror signal MIRR is generated by the waveforms J and K. When the optical recording / reproducing apparatus is normally operated, that is, in the normal search mode instead of the high speed, the mirror is error free. The signal is obtained without any problems.

However, in the high-speed search mode in which the sled motor must move, not in the normal search mode, errors of the mirror signal often occur as shown in FIG. 3.

In other words, when the waveform J does not cross on the waveform K as in the case of the display points e1 and e2 in FIG. 3, the mirror signal is an error mirror signal.

The reason for this is ascertained by the circuit as shown in FIG. 1, in the high-speed search, the voltage of the waveform J charged in the capacitor C2 is recharged even before being sufficiently discharged. It can be seen that the waveform J level increases.

Accordingly, it can be concluded that the level of the input RF signal should be adjusted according to the normal search or the fast search mode in order to always cross the waveform J at the normal search and the fast search at the level of the waveform K. will be.

That is, the above conclusion is included in the lofty concept for the applicant to discover the problem and solve it.

As described above, the conventional mirror circuit has a problem of causing an error of the mirror signal during high-speed search.

The above problem is a factor that causes the sled servo to make a large error in generating track counting data (one pulse generated by one track movement) using the mirror signal and the track zero crossing signal. Therefore, it is apparent that even a microcomputer, which is a control unit of the system which controls the sled servo by input counting the track counting data, will also malfunction.

Accordingly, an object of the present invention is to solve the conventional problems as described above.

Another object of the present invention is to provide a signal control circuit of an optical recording and reproducing apparatus capable of generating an error-free mirror signal.

Still another object of the present invention is to provide a signal adjusting circuit which can improve the reliability of the optical recording and reproducing apparatus.

According to the present invention for achieving the above objects, there is provided an optical recording and reproducing apparatus having a mirror signal generating circuit having first and second input ends and a first output end, wherein the first and second input ends are connected to each other. A capacitor for passing only an alternating current component of an RF signal applied from a first input terminal, and connected between the first input terminal and the second output terminal, read from a recording medium of the optical recording and reproducing apparatus, and then applied to the first input terminal. Resistor means for attenuating the input voltage of the RF signal, and a control means connected to the resistance means for adjusting the resistance value of the resistance means in accordance with the first and second operating modes of the optical recording and reproducing apparatus are provided in circuit. do.

According to the present invention as described above, an error-free mirror signal may be generated by the mirror circuit in either the normal search mode or the fast search mode.

Hereinafter, with reference to the accompanying drawings, the configuration and operation will be described in detail.

4 is a signal control circuit diagram according to the present invention, and shows the overall connection relationship with the mirror signal generation circuit 100 of FIG.

The capacitor C connected between the first output terminal RFO and the second input terminal RFI has the same function as the capacitor C1 of FIG.

The resistance means connected between the first input terminal RF- and the first output terminal RFO corresponds to a resistor R1, R2, R3, and the adjusting means is a switching transistor 20 or a microcomputer 10. Corresponds to.

Referring to the specific embodiment and the effect of the present invention based on the above-described configuration and description, for example, assume that the output terminal (D) of the microcomputer 10 in the normal search mode is "high".

Accordingly, the switching transistor 20 is “turned on” and the power supply voltage VG applied to the emitter of the transistor 20 will be moved to the resistance means 30 by the potential difference thereof.

In this case, let's define the first operation mode.

On the other hand, if the output terminal of the microcomputer 10 is "low" in the high-speed search mode (second operation mode), the resistance value of the resistance means 30 will increase than in the first operation mode.

Therefore, the RF signal applied to the first input terminal RF- will be reduced by the change of the resistance value, and the waveform will be the same as the waveform J of FIG. 3 from the waveform of the waveform J of FIG.

Therefore, even in the high-speed search mode, an error-free mirror signal such as waveform MIRR of FIG. 2 is generated by the mirror signal generation circuit 100.

Also, the programming of the microcomputer 10 to change the signal of the output terminal D according to the normal search mode or the high speed search mode may be performed by anyone skilled in the art.

As long as the signal of the output terminal D of the microcomputer 10 is changed to high or low, and the use type of the transistor 20 can be replaced with the NPN or PNP type without departing from the lofty concept of the present invention as described above. Of course, it will be understood by those of ordinary skill in the art that various changes and modifications are possible.

According to the present invention as described above, since there is an advantage that the error of the mirror signal can be prevented by adjusting the input of the RF signal applied from the pickup when the information on the disk is searched at high speed, the reliability of the system is improved.

Claims (4)

An optical recording and reproducing apparatus having a mirror signal generating circuit having first and second input terminals and a first output terminal, comprising: only an AC component of an RF signal connected between the first output terminal and the second input terminal and applied from the first input terminal; A capacitor for passing therethrough, and resistance means connected between said first input terminal and said first output terminal to attenuate an input of said RF signal applied to said first input terminal after being read from a recording medium of said optical recording / reproducing apparatus; And an adjusting means connected to the resistance means for adjusting the resistance value of the resistance means in accordance with the first and second operation modes of the optical recording and reproducing apparatus. The signal control circuit according to claim 1, wherein the resistance value is increased when any one of the first and second operation modes is a high speed search mode. 2. The signal regulating circuit according to claim 1, wherein said regulating means comprises a switching transistor which is turned on or off in accordance with said first and second operating modes. 4. The signal control circuit according to claim 3, wherein said control means comprises a microcomputer for applying a high or low signal to said switching transistor in accordance with said first and second operating modes.