KR0162395B1 - Reflectivity compensation device of cd-rom drive disk - Google Patents

Abstract

The present invention relates to a disk reflectance compensation device of a CD-ROM drive. Conventionally, CD-ROM disks used in the related art have different reflectances according to manufacturers, and CD-WORM DISCs (write once discs) Since the difference in reflectance is more severe, when the data of discs having different reflectances are read, the amplitude of the signal is large and small depending on the discs. Therefore, there is a problem that a lot of errors occur during data reproduction in discs having low reflectances. Therefore, in the present invention, when the disk reflectance is low, the laser light amount is made larger than that of the normal disk, so that the amplitude of the optical signal read from the disk is increased so that data can be reproduced without error.

Description

Disc Reflectance Compensator for CD-ROM Drives

1 is a circuit diagram of a conventional CD-ROM drive.

2 is a diagram of a high frequency output voltage waveform according to the reflectance of the disk in FIG.

3 is a circuit diagram of a disk reflectance compensation device of a CD-ROM drive according to the present invention.

4 is an output waveform diagram of each part in FIG. 3 when the disk reflectance before compensation is low.

5 is an output waveform diagram of each part of the disk reflectance after compensation in FIG.

* Explanation of symbols for main parts of the drawings

1 disc 2 imaging lens

3: beam splitter 4: photosensor

5 amplification unit 6 comparative amplification unit

7: laser module 8: reflectance compensator

81: amplitude detection section 81a: peak-hold section

81b: bottom-hold part 82: comparison part

83: drive voltage control unit 83a: analog / digital conversion unit

83b: microcomputer 83c: digital / analog converter

Disclosure of Invention The present invention relates to reading data on a disc using a laser light in a CD-ROM drive. In particular, a disc of a CD-ROM drive can reproduce data without errors by actively adjusting a laser light quantity reference signal according to a disk reflectance. It relates to a reflectance compensation device.

As shown in FIG. 1, the circuit structure of the conventional CD-ROM drive includes: an imaging lens 2 for condensing laser light emitted from the laser diode LD as a light source onto the surface of the disk 1; A beam splitter 3 for changing the direction of light reflected and diffracted by the disk 1, a photosensor 4 for detecting the amount of light received from the beam splitter 3, converting the light signal into a corresponding optical signal, and outputting the light signal; An amplification unit 5 for amplifying and outputting the optical signal detected by the photosensor 4 to a predetermined level, a photodiode PD for detecting the light quantity of the laser generated by the laser diode LD; A comparison amplifier 6 for comparing the output voltage according to the amount of light of the photodiode PD with a reference voltage generated by the variable resistor, amplifying the comparison result to a predetermined level, and outputting the amplification result at a predetermined level; On or off depending on the output of the It is configured to drive the low-diode (LD) with a laser drive transistor (Tr) for controlling.

In the above, the laser diode LD and the photodiode PD gather to form the laser module 7.

The prior art constructed as described above will be described with reference to FIGS. 1 and 2.

First, when laser light is generated from the laser diode LD, which is a light source of the laser module 7, this laser light is focused on the disk 1 surface by the imaging lens 2.

When the laser light focused on the surface of the disk 1 is reflected and diffracted from the disk 1 and incident on the beam splitter 3, the beam splitter 3 changes the direction and sends the beam to the photosensor 4.

Then, when the photosensor 4 converts the amount of reflected and incident light into current and outputs it to the amplifier 5, the amplifier 5 converts the voltage back into a voltage proportional to the current, and changes the changed voltage. Amplified to a level and outputted, the voltage VRF becomes a basic signal for reading data on the disk as a high frequency signal.

The photodiode PD detects an amount of laser light generated by the laser diode LD, and a photosensitive current IP flows through the detected photodiode PD, and a voltage proportional to the photosensitive current IP VP is input to the non-inverting terminal + of the amplifier OP1 in the comparison amplifier 6, and the reference voltage Vref determined by the variable resistor VR1 is input to the inverting terminal-.

The comparator OP1 compares the two voltages and outputs a voltage V _LD proportional to the compared voltage difference.

Then, the voltage V _LD is applied to the base of the laser driving transistor Tr to adjust the laser driving current flowing through the laser diode LD, so that the amount of laser generated light of the laser diode LD is always constant. maintain.

In this case, in order to control the laser light amount, the reference voltage Vref may be adjusted, which should be adjusted to the variable resistor VR1, which is fixed at an appropriate value during manufacture of the product.

Referring to the operation process of the comparison amplifier 6 again, the photodiode PD is a sensor for compensating for a decrease in light output according to the temperature of the laser diode LD. When the output is small, the photosensitive current Ip is thus reduced, and as a result, the voltage V _LD of the amplifier OP1 is decreased, so that the current I _L of the laser driving transistor Tr is increased to increase the laser diode ( LD) recovers the light output.

Since the amount of laser light projected onto the disk 1 is always constant in the above, the amount of light reflected from the disk 1 is eventually changed according to the reflectance of the disk 1, and as shown in (a) of FIG. When high, the signal amplitude of the finally output high frequency output voltage VRF is large, and when the disk reflectance is low, the signal amplitude of the high frequency output voltage VRF is small as shown in FIG.

However, in the conventional technology as described above, the CD-ROM discs currently used vary in reflectance depending on the manufacturer, and the CD-WORM discs (CD-WORM DISC: recordable discs) have a greater difference in reflectance.

Therefore, as described above, when data of discs having different reflectances are read, the signal amplitude is large and small depending on the discs, and thus, a disc having a low reflectance causes a lot of errors during data reproduction.

Accordingly, an object of the present invention is to provide a disk reflectance compensation device of a CD-ROM drive, which prevents an error from occurring during data reproduction by adjusting the laser light quantity reference signal differently according to the disk reflectance.

The present invention for achieving the above object is a laser module consisting of a laser diode for generating a laser light and a photodiode for detecting the amount of light generated by the laser diode, and the imaging lens to the laser light emitted from the laser diode to the disk When the light is collected, an amplifying means converts an optical signal of the amount of light reflected and diffracted from the disk into a voltage, amplifies it to a predetermined level, and outputs the final output voltage, and compensates the reflectance by receiving the output signal of the amplifying means. Reflectance compensating means for outputting the received signal, a comparison amplifying means for receiving and comparing the output signal of the reflectance compensating means and the output signal of the laser module, and outputting a voltage according to the comparison difference, and the output of the comparing amplifying means Laser driving means that adjust the laser light quantity of the laser module according to the voltage Configure.

Referring to the operation and effect of the present invention configured as described in detail as follows.

3 is a block diagram of a disk reflectance compensator for a CD-ROM drive according to the present invention. As shown in FIG. 3, the laser diode LD generating laser light as a light source and the laser light generated from the laser diode LD are shown in FIG. Laser module 7 made of photodiode PD for detecting, imaging lens 2 for condensing laser light emitted from laser diode LD on the surface of disk 1, and disk 1 Beam splitter 3 for changing the direction of the reflected and diffracted light in the beam), a photo sensor 4 for detecting the amount of light received from the beam splitter 3, converting the light signal into a corresponding optical signal, and outputting the light signal; The amplification unit 5 converts the optical signal detected through (4) into a voltage, amplifies the signal to a predetermined level, and finally outputs the reflection signal from the disk according to the output voltage transmitted from the amplification unit 5, that is, reflectance. Signal The reflectance compensator 8 compensates and outputs a signal having the same size, and the output signal compensated by the reflectance compensator 8 and the output signal according to the amount of light output from the laser module 7 are compared. A comparison amplifier 6 for amplifying and outputting a difference to a predetermined level, and a laser driving transistor Tr that is turned on or off according to the output of the comparison amplifier 6 to control the driving of the laser diode LD. It consists of.

In the above, the reflectance compensator 8 receives an output voltage of the amplifier 5 and outputs a voltage Vpp representing an amplitude proportional to the voltage, and an amplitude detector 81 of the amplitude detector 81. The comparison unit 82 for comparing the output voltage Vpp and the reference voltage Vrp by the variable resistor VR2 and outputting the voltage Vd according to the difference, and the comparison output of the comparison unit 82. It consists of a drive voltage adjusting unit 83 for generating a disk drive voltage according to.

Referring to the operation and effect of the present invention configured as described in detail as follows.

When the laser module 7 generates laser light from the laser diode LD as a light source, the laser light is focused on the disk 1 through the imaging lens 2 and the focused light is emitted from the disk 1. As it is reflected and transmitted to the beam splitter 3, the beam splitter 3 turns to the photosensor 4.

Here, assume that the disk has a low reflectance of the disk 1.

Then, when the photosensor 4 converts the amount of light reflected from the disk 1 into the current and outputs it to the amplifier 5, the amplifier 5 changes the voltage proportional to the current again. The amplified voltage is amplified to a certain level and outputted. The voltage (V _RF ) is a high frequency signal and becomes a basic signal for reading data on the disk.

The voltage V _RF output from the amplifier 5 is as shown in FIG.

When the voltage V _RF output from the amplifier 5 is transferred from the reflectance compensator 8 to the peak-hold unit 81a and the bottom-hold unit 81b of the amplitude detector 81, the peak The hold part 81a temporarily accumulates the peak amplitude of the output voltage V _RF of the amplifier 5, detects only the voltage Vpeak corresponding to the highest peak value among the accumulated amplitudes, and Output to the non-inverting terminal (+), the bottom-hold portion 81b similarly temporarily accumulates the bottom amplitude of the output voltage V _RF of the amplifier 5 and corresponds to the lowest bottom value among the accumulated amplitudes. Only the voltage Vbottom is detected and output to the inverting terminal (-) of the amplifier 81c.

Therefore, the amplifier 81c compares the highest peak value with the lowest bottom value, and the amplitude of the comparison difference, that is, the amplitude voltage representing the amplitude of the output voltage V _RF of the amplifier 5 as shown in FIG. Outputs (Vpp).

The amplitude voltage Vpp is proportional to the reflectance of the disk and is preset by the variable resistor VR2 input to the inverting terminal (-) of the amplifier OP2 of the comparator 82 and to the non-inverting terminal (+). It is compared with the reference voltage Vrp and outputs a comparison voltage Vd according to the comparison difference, that is, a voltage Vd as shown in FIG. 4C.

The comparison voltage (Vd) is an information value of how the difference of the reflectance of the disc currently being read from the preset reference value is converted into digital data through the analog-to-digital converter (83a) of the driving voltage adjusting unit (83). It is input to 83b.

The microcomputer 83b receives data corresponding to the disk reflectance through the analog / digital converter 83a, and when the value is small, that is, when the reflectance is low, the large data is passed through the digital / analog converter 83c. The signal is converted to an analog signal and output to the comparison amplifier 6, and the signal output through the digital / analog converter 83c is a higher voltage than the previous one as the reference voltage Vref as shown in FIG.

The reference voltage Vref transmitted to the comparison amplifier 6 is input to the inverting terminal (-) of the amplifier OP1 and compared with the voltage input to the non-inverting terminal (+) of the amplifier OP1. The voltage inputted to) is a photovoltaic current Ip in proportion to the amount of light detected by the photodiode PD of the laser module 7, and is a voltage Vp corresponding to the photosensitive current Ip.

Accordingly, the comparison voltage V _{LD obtained} by comparatively amplifying the two voltages Vp Vref is output from the amplifier OP1, and the comparison voltage V _LD becomes a voltage lower than the previous voltage, so that the laser driving transistor ( As applied to the base of Tr, the laser driving transistor TR is turned on so that the laser driving current I _L as shown in FIG. 4 (e) is increased so that the laser diode LD of the laser module 7 is increased. ) Will increase the light output.

Since the light output of the laser diode LD is increased, the signal V _RF reflected from the disk 1 becomes larger than before, and thus is compensated by a signal having the same size as the signal reflected from the disk having a high reflectance. do.

That is, as shown in (a) to (e) of FIG. 5, the reflectance is a signal compensated for and output.

As described in detail above, the present invention generates a lot of errors in data conversion due to the small amplitude of the optical signal read from the disk during data reproduction of the disk having low reflectance, and in some cases, it is impossible to reproduce the disk data. When the reflectance is low, the laser light amount is larger than that of a normal disk, so that the amplitude of the optical signal read from the disk is increased so that data can be reproduced without error.

Claims (4)

A laser module comprising a laser diode that generates laser light and a photodiode that detects the amount of light generated by the laser diode, and when the imaging lens condenses the laser light emitted from the laser diode onto the disk, it is reflected and diffracted from the disk. Amplifying means for converting an optical signal for the amount of light received into a voltage and amplifying the light signal to a predetermined level and outputting the final output voltage; A comparison amplification means for receiving an output signal of the reflectance compensating means and an output signal of the laser module, and outputting a voltage according to the comparison difference, and an amount of laser light of the laser module according to the output voltage of the comparison amplification means. CD-ROM characterized by consisting of a laser drive means for adjusting Disk reflectivity compensation apparatus of Eve. The method according to claim 1, wherein the reflectance compensating means comprises: amplitude detecting means for receiving an output voltage of the amplifying means and outputting a voltage representing an amplitude proportional to the voltage, comparing the output voltage of the amplitude detecting means with a reference voltage, Comparing means for outputting a voltage according to the comparison difference, and the disk reflectance compensation device of the CD-ROM drive, characterized in that the drive voltage adjusting means for generating a disk drive voltage according to the comparison output of the comparison means. 3. The amplitude detecting means according to claim 2, wherein the amplitude detecting means temporarily accumulates the peak amplitude from the signal reflected from the disk, obtains and outputs the peak value at that time, and the bottom from the signal reflected from the disk. The bottom-holding means for temporarily storing the amplitude and calculating the bottom value at that time, and the output voltage of the peak-holding means is input to the non-inverting terminal (+), and the output voltage of the bottom-holding means is inverted. And amplifying means for comparing the two voltage values, and amplifying the difference to a predetermined level. The method of claim 2, wherein the driving voltage adjusting means is an analog / digital conversion means for converting the input disk reflectance signal to a digital value and outputs, and adjusts and outputs a reference voltage in accordance with the output signal of the analog / digital conversion means And a digital / analog converting means for converting an output value of the microcomputer into an analog signal and outputting the converted signal.