KR20000033029A - Circuit for generating stable focus ok signal - Google Patents

Abstract

PURPOSE: A circuit for generating a stable focus OK signal is provided. CONSTITUTION: In a focus servo device for compensating a focus error generated due to up and low vibration of a disc, a circuit(1) for generating a stable focus OK signal comprises an RF amplification unit(11) for outputting an RF amplification signal by adding an inputted beam signal; an upper limit envelop signal generating unit(12) for receiving the RF amplification signal, and outputting its upper limit envelop signal; a lower limit envelop signal generating unit(13) for receiving the RF amplification signal, and outputting its lower limit envelop signal; an addition unit(14) for adding the upper and lower limit envelop signals from the upper and lower limit envelop signal generating units(12,13); a predetermined level detection unit(15) for calculating a peak value of a focus error signal obtained by adding and subtracting the beam signal, and detecting a zero cross time of the focus error signal from the peak value; a switch(16) for passing an addition signal from the addition unit(14) by switching at the detection point; and a comparison unit(17) for generating a focus OK signal by comparing the addition signal passed through the switch(16) with a predetermined slide voltage according to a size of the disc.

Description

Stabilized Focus OK Signal Generation Circuit

The present invention relates to an optical system, and more particularly, to a stabilized focus ok signal generating circuit which enables to stabilize a focus ok signal generating circuit which starts to correct a focus error caused by vibration of a disc.

With the development of audio and video media, optical disc players have been developed for recording and reproducing video and audio data on semi-permanent optical discs.

Such an optical disc player reproduces video and / or audio recorded on an optical disc and outputs it through a screen and / or a speaker, and has a higher signal-to-noise ratio than conventional video and / or audio reproducing apparatus, resulting in better image quality and / or Or, it can reproduce signals with sound quality, generates no noise due to irregular playback and modulation, has very little distortion, no ghost, no random access, and has a number of advantages. There is a trend that is widespread.

These optical disc players also include compact disc players (CDPs), laser disk players (LDPs) and compact disc graphics players (CDGPs), and video compact disc players (VCDPs: vidos). The compact dist player has been developed and widely used, or recently, a digital video disk (DVD) using MPEG-2 moving image compression technology and a digital video disk player for playing the same have been developed. It can record and play back gigabytes (GB) of data, including moving images, on a 12cm optical disc.

Here, the compact disc player is largely composed of an optical system, a motor drive system and a signal system. In other words, the data engraved on the pit of the compact disc is irradiated through the optical signal, and is read out by using the light quantity difference of the beam returned by the irradiated beam.

In such a compact disc player, the data format structure of the disc D inserted in the tray E of the compact disc player is as shown in Fig. 1A. That is, the disc D is composed of a lead-in area B, a program area B ', and a lead-out area C. The disc D has a disc inside the lead-in area B, which is an inner circumferential part of the disc D. The number of songs recorded, the time and total time of each song, and the table of contents (TOC) in which the addresses of the first part and the index part of each song are recorded are repeatedly recorded.

The actual data is recorded in the program area B ', and in order to read such data, the optical pickup actuator P is transferred in the inner circumferential direction A of the disk D to read the disk D. After reading thio data recorded in the phosphorus area B, it moves to the outer circumferential direction A '. Then, the sub cue signal is checked while the track of the program area B 'is jumped to reproduce the desired song.

That is, in the disc player for reproducing such a disc, the focus error generated when the disc vibrates up and down is compensated according to the beam signal formed on the photodiode through the objective lens of the actuator.

That is, first, the astigmatism method for detecting the beam shape by defocusing is adopted as the detection method of the focus error signal from the formed beam signal of the photodiode. The astigmatism method is as follows. The beam irradiated from the light emitting diode passes through the objective lens and is reflected on the disk D, and the beam reflected from the disk D is imaged on a quadrant photo diode.

At this time, the cross-section of the beam formed on the 4-split photodiode is shown in FIG. 1B. That is, FIG. 1B (A) shows the shape of the beam of the four-segment photodiode (ad) when the focal point is close, and FIG. 1B (B) shows the shape of the beam of the four-segment photodiode when the focal point is exactly the same. FIG. 1B (C) shows the shape of the beam of the quadrant grape diode (ad) when the focal point is far.

As shown in FIG. 2A, a focus servo device that compensates for a focus error from the beam signal ad adds and subtracts a beam signal generated from the photodiode ad to the RF amplification signal RFO and the focus error. An RF amplifying unit 71 for generating a signal FE, a focus ok signal generating circuit 73 for generating a focus ok signal FOK for receiving the RF amplifying signal RFO and performing focus adjustment; The microcomputer 75 generates a control signal for compensating the focus error by receiving the ok signal FOK, and a compensation signal for compensating the focus error according to the control signal of the microcomputer 75 and the focus error signal FE. And a compensation unit 77 for generating a compensation signal and supplying the compensation signal to a focus coil (not shown) of the actuator P.

Here, as shown in FIG. 2B, the focus ok signal generating circuit 73 includes a DC component removing unit 80 for removing a DC component of the RF amplified signal RFO and a DC component removing unit 80. The differential amplifier 82 differentially amplifies the output signal RFI and the RF amplification signal RFO, and the output signal FAM of the differential amplifier 82 and initially set according to the type of disc. And a comparator 84 for outputting a focus ok signal FOK in comparison with the slide voltage REF that varies according to the rotational speed of the disk.

In the conventional focus servo device configured as described above, first, the beam signal ad formed from the four-segment photodiode is supplied to the RF amplifier 71, and the RF amplifier 71 adds all the beam signals to RF amplification. Output the signal RFO. The RF amplified signal (RFO) is as shown in Figure 3 (A).

The RF amplified signal (RFO) is supplied to the DC component remover 80 of the focus OK signal generating circuit 73, the DC component remover 80 removes the DC component of the RF amplified signal (RFO), DC The output signal RFI of the component removing unit 80 is supplied to the differential amplifier 82.

The differential amplifier 82 supplies the RF amplifier signal RFO and the output signal RFI of the DC component remover 80 to the differential amplifier 82, and the differential amplifier 82 supplies the RF amplifier signal RFO. ) And the output signal RFI are subtracted and amplified, and the output signal FAM of the differential amplifier 82 is as shown in FIG.

The output signal FAM of the differential amplifier 82 is supplied to the comparator 84, and the comparator 84 receives the slide voltage REF from the microcomputer 75 to output the differential amplifier 82. The magnitudes of the signal RAM and the slide voltage REF are compared to output a focus ok signal FOK as shown in FIG. 3C.

The focus ok signal FOK as described above is supplied to the microcomputer 75, and the microcomputer 75 outputs a control signal for compensating for a focus error from when the focus ok signal FOK transitions from a low level to a high level, The control signal is supplied to the compensator 77, and the compensator 77 generates a compensation signal for compensating the focus error, and supplies the compensation signal to a focus coil (not shown) of the actuator P. Therefore, the focus error due to the up and down vibration of the disk can be compensated.

In the conventional focus ok signal generating circuit as described above, a three-beam RF amplification signal composed of a beam formed on a four-segment photodiode and two beams generated from a one-segment photodiode and an RF amplified signal having a DC component are input. In this case, the focus ok signal is detected by the astigmatism method, but in the case of a digital video disc having a one-beam method formed on a quadrature diode, the focus ok signal cannot be detected. Therefore, there is a problem that the conventional focus ok signal generating circuit cannot be compatible.

SUMMARY OF THE INVENTION The present invention has been made to solve such a problem, and an object of the present invention is to generate a focus ok signal from an RF signal and a focus error signal, thereby providing a stabilized focus ok signal generating circuit capable of operating stably in all optical systems. I would like to.

According to an aspect of the present invention, there is provided a focus servo device for compensating a focus error caused by a vertical vibration of a disk, including: an RF amplifier for adding an RF signal and outputting an RF amplified signal; An upper limit envelope signal generator for receiving an amplified signal and outputting an upper limit envelope signal of the RF amplified signal, a lower limit envelope signal generator for receiving an RF amplified signal of the RF amplifier and outputting a lower limit envelope signal of the RF amplified signal, and the upper limit The peak value of the focus error signal obtained by adding and subtracting the beam signal after adding the upper and lower envelope signals and the lower envelope signal, and the beam signal generating unit and the lower envelope signal generation unit, calculates the peak error signal from the calculated peak value. The predetermined level detector which calculates the time point at which the Generated a stabilized focus ok signal consisting of a switch for switching at the time of detection and passing the addition signal of the adder, and a comparator for generating the focus ok signal by comparing the amplified signal passed through the switch with a slide voltage set according to the size of the disc. It is characterized by consisting of a circuit.

1A is a diagram for explaining an area of a disc mounted in a general CD player.

1B is a cross-sectional view of a beam formed on a photodiode according to a distance between a conventional disk and an objective lens.

Figure 2a is a block diagram showing the configuration of a general focus servo device.

FIG. 2B is a diagram showing the configuration of a focus ok signal generating circuit in FIG. 2A; FIG.

Figure 3 is a view showing the output waveform of each part in Figure 2b.

4 is a diagram showing a configuration of a focus ok signal generating circuit to which the present invention is applied;

FIG. 5 is a view illustrating output waveforms of respective parts of FIG. 4; FIG.

<Description of the code | symbol about the main part of drawing>

1: Focus OK signal generating circuit 3: Microcomputer

5: Focus error signal generator 7: Compensator

11: RF amplification unit 12: upper limit envelope signal generation unit

13: Lower limit envelope signal generator 14: Adder

15: predetermined level detection unit 16: switch

17: comparison unit P: actuator

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

4 is a diagram illustrating a configuration of a focus servo device to which the present invention is applied. Here, the RF amplifier 11 generates an RF amplified signal (RFO) by adding the beam signal generated from the photodiode (ad), and the upper limit envelope signal of the RF amplified signal (RFO) in response to the RF amplified signal (RFO). An upper limit envelope signal generation unit 12 for outputting (UES) and a lower limit for outputting the lower limit envelope signal LES of the RF amplified signal RFO by receiving the RF amplified signal RFO of the RF amplifier 1. An adder 14 which adds an upper limit envelope signal UES and a lower limit envelope signal LES of an envelope signal generator 13, the upper envelope signal generator 12, and the lower envelope signal generator 13; A predetermined level detector 15 for calculating a peak value of the focus error signal FE, and calculating a time point at which the focus error signal FE crosses zero from the calculated peak value; and a viewpoint detected by the predetermined level detector 15. Switch 16 for passing through the addition signal of the adder 14 by switching in, Focus error correction is started including a comparator 17 for generating a focus ok signal FOK by comparing the addition signal FAD passing through the switch 16 with a slide voltage REF preset according to the type of the disc. The microcomputer 3 which receives the focus ok signal FOK and generates a control signal for compensating for a focus error is connected to the output side of the focus ok signal generating circuit 1 for outputting the focus ok signal FOK.

On the other hand, the output side of the focus error signal generator 5 which subtracts the beam signal ad to generate the focus error signal FE is used to compensate for the focus error signal FE according to the control signal of the microcomputer 5. A compensation unit 7 for generating a compensation signal and supplying the compensation signal to the actuator P is connected.

The operation and effect of the focus servo device applied to the present invention thus constructed will be described with reference to FIG.

The beam signal ad supplied from the 4-split photodiode is supplied to the RF amplifier 11 of the focus ok signal generating circuit 1, and the RF amplifier 11 adds the beam signal ad to FIG. An RF amplified signal RFO as shown in A) is output, and the RF amplified signal RFO satisfies the following equation.

RF amplified signal (RFO) = (a + c) + (b + d)

The RF amplified signal RFO is supplied to an upper envelope signal generator 12 and a lower envelope signal generator 13, and the upper envelope signal generator 12 is an envelope for the peak value of the RF amplifier signal RFO. The upper limit envelope signal UES as shown in Fig. 5B. Then, the lower envelope signal generator 13 envelopes the lower limit of the RF amplification signal RFO and outputs the lower envelope signal LES as shown in FIG. 5C.

The upper envelope signal UES and the lower envelope signal LES are supplied to the adder 14, and the adder 14 adds the upper envelope signal UES and the lower envelope signal LES to FIG. 5 (D). And outputs an addition signal FAD as shown in FIG.

On the other hand, the beam signal ad supplied from the four-segment photodiode is supplied to the focus error signal generator 5, and the focus error signal generator 5 adds the beam signals a and c, and the beam signal. (b) and (d) are added, and the addition signals a + c and b + d are respectively subtracted to output a focus error signal FE as shown in Fig. 5E. That is, the focus error signal FE satisfies the following equation.

Focus error signal FE = (a + c)-(b + d)

The focus error signal FE is supplied to the predetermined level detector 15, and the predetermined level detector 15 calculates a peak value of the focus error signal FE, and zeros the focus error signal FE from the calculated peak value. The switch 16 is connected to the predetermined level detector 15 that calculates the point in time T to cross, and the point of time T detected by the predetermined level detector 15.

The addition signal FAD of the adder 14 passing through the switch 16 is supplied to the comparator 17, and the comparator 17 is compared with the slice voltage REF supplied from the microcomputer 3. The focus ok signal FOK as shown in FIG. 5F is output.

The focus ok signal FOK generated by the focus ok signal generating circuit 1 is supplied to the microcomputer 3, and the microcomputer 3 receives the focus when the focus ok signal FOK transitions from a low level to a high level. A control signal for compensating the error signal FE is generated, and the control signal and the focus error signal FE are supplied to the compensator 7.

The compensation unit 7 operates according to the control signal to output a compensation signal for compensating the focus error signal FE, and the compensation signal is supplied to an objective lens driver (not shown) of the actuator P. The objective lens is moved up or down according to the compensation signal.

As described above, since the stabilized focus ok signal generating circuit according to the present invention generates the focus ok signal according to the RF amplification signal and the focus error signal, the focus ok signal can be stabilized, and for all models. It has the effect of being compatible.

Claims (1)

An RF amplifying unit which adds an input beam signal and outputs an RF amplified signal; An upper limit envelope signal generation unit receiving the RF amplification signal of the RF amplifying unit and outputting an upper limit envelope signal of the RF amplifying signal; A lower envelope signal generator for receiving an RF amplified signal of the RF amplifier and outputting a lower envelope signal of the RF amplified signal; An adder configured to add an upper limit envelope signal and a lower limit envelope signal to the upper limit envelope signal generator and the lower limit envelope signal generator; A predetermined level detector which calculates a peak value of the focus error signal obtained by adding and subtracting the beam signal, and calculates a time point at which the focus error signal crosses zero from the calculated peak value; A switch for switching at the time point detected by the predetermined level detector to pass the addition signal of the adder; And a comparator for generating a focus ok signal by comparing the amplified signal passing through the switch with a slide voltage preset according to a size of a disk.