DE4209890A1 - Optical disc drive with intensity controlled laser diode - separates received signal into high and low frequency current components that are summed and amplified - Google Patents

Abstract

The optical disc drive uses a laser diode (9) to generate a beam focussed onto the disc. The reflected signal is received by a photodiode (PD). The current produced (IM) provides high and low frequency components that are filtered (62) to separate the components. The low frequency signal (IML) is amplified (A) and is summed with the high frequency current (IML) and the resulting signal is amplified (A2) to generate a voltage to control the intensity of the laser diode output by use of a filter (63) and control stage (60). ADVANTAGE - Provides broad band stabilising operation.

Description

The invention relates to a disk drive for optical Disks, especially an optical disk drive Record or play back data stored on tracks an optical disc or are recorded, while the optical disk is relative to an optical Head turns.

An image file system contains a disk drive for opti plates. An optical one rotates in this drive Plate on which a large number of tracks spiral or is concentric, and thereby be on the Traces data recorded or data from the traces sen.

A template is scanned in two dimensions in order to capture it th image data of the template in electrical image data photo implement electrically, and the electrical image data who optically on the traces of the optical disc with the help of an optical head. To recover d. H. to read the data, the recorded data read from the optical head to hard or soft knockout pie to be represented.

This takes place in a disk drive for optical disks Record data on an optical disc with the help  of a laser beam emitted by a semiconductor laser oscilla tor (a light source) is output in the optical head and reading from on the optical disc recorded data is done by converting the laser beam into an electrical signal using one in the optical Head detector, and then that electrical signal converted into a video signal.

The strength of the abge by the semiconductor laser oscillator beamed laser beam is from a laser beam controller controlled. This laser beam control is designed that they are caused by temperature changes in the semiconductor laser oscillator-induced changes in the laser beam hand a threshold current with the help of a control corri gier, whereby from a monitoring current regarding the La serstrahls is used so that the amount of light con keep stant.

In particular, a monitoring or Monitor current for one of the semiconductor laser oscillators coming laser beam output. The output Monitoring current is converted into a voltage. The Strength of the emitted by the semiconductor laser oscillator The laser beam is controlled in accordance with this voltage.

However, with the conventional disk drive, the tape width of this scheme is narrow, the laser changes beam output power of the semiconductor laser oscillator due to backward light disturbances. This does not affect inevitably both data and control signals. By a insufficient response speed to a recording The light impulse can be based on a light quantity control a feedback control was not carried out who the.  

The object of the invention is to provide a disk drive for opti cal plates to indicate which is the laser beam output performance of a laser beam source in an optical head can stabilize broadband.

The solution to this problem is specified in the claims.

In the following preferred embodiments of the Er Finding explained in more detail with reference to the drawing. Show it:

Fig. 1 is a schematic block diagram of an embodiment of a disk drive for optical disks;

Fig. 2 is a circuit diagram of the structure of the laser control device according to Fig. 1;

Fig. 3 is a circuit diagram of the structure of a pulse shaper circuit according to Fig. 2,

FIGS. 4A to 4D are pulse diagrams of which illustrate signal waveforms at various portions in Figure 3 gezeig th pulse shaper. and

Fig. 5 is a circuit diagram of the structure of a variable current source of FIG. 3.

Fig. 1 shows schematically an embodiment of a disk drive for optical disks according to the invention.

The optical disk drive is designed to record data on an optical disk 1 , reproduce data from the optical disk 1 , or erase data recorded on the optical disk 1 by a focused beam onto the optical disk Plate 1 is directed.

In a surface of the optical Plat shown in Fig. 1 te 1 are grooves (tracks) formed either spirally or concentrated symmetrical. The plate 1 is rotated by a motor 2 at a constant speed (e.g. 1800 RPM). The motor 2 is controlled by a motor control circuit 18 .

Although the optical disc 1 has a recording film or a recording layer in which small holes (pits) are formed, a recording layer based on a phase change can also be used, or a multilayer recording film can also be used.

An optical head 3 is arranged near the bottom of the plate 1 . With the aid of this optical head 3, data is recorded / reproduced on or from the optical disk 1 .

The optical head 3 is attached to a driver coil 13 as a movable section of a linear motor 31 . The driver coil 13 is connected to a linear motor control circuit 17 . A linear motor position detector 26 is connected to this linear motor control circuit 17 . He put through an opening formed on the optical head 3 opti rule scale 25 indicates the linear motor position detector 26, a position signal.

A permanent magnet (not shown) is arranged on the fixed section of the linear motor 31 . When the driver coil 13 is energized by the linear motor control circuit 17 to activate the linear motor 31 , a laser beam emitted from the optical head 3 is moved in the radial direction of the optical disk 1 .

As shown in Fig. 1, the optical head 3 includes an objective lens 6 , drive coils 4 and 5 for driving the objective lens 6 , a photodetector 8 , a laser diode 9 as a semiconductor laser oscillator, a condenser lens 10 a, a cylindrical lens 10 b, one Collimator lens 11 a for Kol limit a laser beam coming from the laser diode 9 , a half prism 11 b and a photodiode PD as a light sensing element for outputting a current which corresponds to the strength of the light emitted by the laser diode 9 .

The objective lens 6 is suspended from a fixed portion (not shown) by means of a wire suspension, as shown in FIG. 1. The objective lens 6 is moved by the driving coil 5 in the focusing direction, that is, in the direction of the optical axis of the objective lens 6 , and it is moved by the driving coil 4 in the tracking direction, that is, in a direction perpendicular to the optical axis of the objective lens 6 .

One of the laser diode 9 , which is controlled by a (yet to be described) laser control circuit 51 , emits ter laser beam is emitted via the collimator lens 11 a, the half prism 11 b and objective lens 6 on the optical plate 1 . Light reflected from the optical plate 1 is guided via the objective lens 6 , the half prism 11 b, the condenser lens 10 a and the cylindrical lens 10 b to the photodetector 8 .

The monitor photodiode PD is disposed in the vicinity of the laser diode 9, and outputs a current that corresponds to the numbers of the La serdiode 9 emitted light quantity. As a detector signal, a monitor current is supplied from the photodiode PD to the laser control circuit 51 . The current output by the photodiode PD comprises high-frequency and low-frequency components.

Here, the laser diode 9 , the photodiode PD and the laser control circuit 51 form a laser beam source.

Referring to FIG. 1 8, the photodetector of four oden Photodi 8 a, 8 b, 8 c and 8 d.

The cathodes of this photodiode 8 a, 8 b, 8 c and 8 d of the photo detector 8 are commonly connected to a preamplifier circuit 52 for video signals, while the anodes are connected to a focusing / tracking circuit 40 .

In this arrangement, currents flow from the cathodes to the anodes in the photodiodes 8 a, 8 b, 8 c and 8 d as a function of the light reflected by the optical plate 1 . Video signal processing is performed using a sum current drawn from the cathodes, whereas focusing (ie, keeping the distance between the optical disk 1 and the objective lens 6 constant) / tracking (tracking a guide track previously on the optical disk 1 was recorded) using the currents derived from the anodes.

As shown in Fig. 1, the focus / track circuit 40 amplifier 12 a, 12 b, 12 c and 12 d, a focus control control circuit 15 , a track control circuit 16 , a linear motor control circuit 17 , adders 30 a, 30 b , 30 c and 30 d and operational amplifier OP 1 and OP 2 .

An output signal of the photodiode 8 a of the photodetector 8 is placed on the amplifier 12 a at one input of the adders 30 a and 30 c. An output signal of the photo diode 8 b is applied via the amplifier 12 b to the input of the adders 30 b and 30 d, respectively. An output signal of the photodiode 8 c is placed on the amplifier 12 c at the other connection of the adders 30 b and 30 c. An output signal of the photodiode 8 d is placed on the amplifier 12 d to the other terminal of the adders 30 a and 30 d.

The output signal of the adder 30 a is applied to the inverting input terminal of the operational amplifier OP 1 , whereas an output signal of the adder 30 b is applied to the non-inverting input of the operational amplifier OP 1 . A track deviation signal corresponding to the difference between the output signals from the adders 30 a and 30 b is given by the operational amplifier OP 1 to the track control circuit 16 . This track control circuit 16 then forms a track driver signal as a function of the track deviation signal supplied by the operational amplifier OP 1 .

The track driver signal output from the track control circuit 16 is given to the driver spool 4 provided for the track direction. Furthermore, the lane departure control signal used by the lane control circuit 16 is given to the line armotor control circuit 17 .

An output signal of the adder 30 c provided to the invertie in power input of the operational amplifier OP 2, whereas an output signal of the adder d applied to the non-inverting input terminal of the operational amplifier OP 2 thirtieth A signal belonging to the focusing point corresponding to the deviation between the output signals of the adders 30 c and 30 d is supplied from the operational amplifier OP 2 to the focusing control circuit 15 . An output signal from the focusing control circuit 15 arrives at the focusing driver coil 5 in order to control the laser beam so that it is precisely focused on the optical disk 1 at all times.

While the focusing and tracking are performed, the sum of the currents due to the output signals from the photodiodes 8a to 8d of the photodetector 8, the output signals of the adders 30 ie a and 30 b, the pre handensein / absence of holes (pits) , that is, recorded information, in the tracks. This signal is converted by the preamplifier circuit 52 for video signals into a voltage value and given to a video signal processing circuit 19 . This video signal processing circuit 19 then reproduces image data and address data (a track number, a sector number and the like).

The laser beam circuit 51 causes the laser diode 9 to respond to a switching signal from a CPU 23 to emit a reproduction light amount corresponding to a laser beam. While the laser beam corresponding to this reproduction light quantity is emitted, the laser control circuit 51 drives the laser diode 9 so that it emits a laser beam corresponding to a quantity of recording light, in accordance with a recording pulse (a template signal) which is signaled by a recording signal. Shaper circuit 41 is supplied.

The output light quantity (reproduction light quantity) of the laser diode 9 is controlled by the laser control circuit 51 in accordance with a monitor current supplied by the photodiode PD.

In addition, a recording signal shaper circuit 34 of the laser control circuit 51 is connected upstream as a modulator. Record data supplied from a disk controller 33 as an external unit through an interface circuit 32 are modulated by the record signal shaping circuit 34 into recording pulses.

That of the video signal processing circuit 19 proces preparing video signal is subjected to processing in the interface circuit 32 to a demodulation or error correction and is output proces 33 then controls to the plates.

The disk drive further includes a digital to analogue converter (DAU) 22 for exchanging information between the focus control circuit 15 , the track control circuit 16 , the linear motor control circuit 17 and the CPU 23 .

The track control circuit 16 moves the objective lens 6 in accordance with a track jump signal which is supplied from the CPU 23 via the digital / analog converter 22 in order to move the laser beam by a distance corresponding to a track.

The laser control circuit 51 , the focus control circuit 15 , the tracking control circuit 16 , the linear motor control circuit 17 , the motor control circuit 18 , the video signal processing circuit 19 , the recording signal shaping circuit 34 and the like are controlled by the CPU 23 via a bus line 20 . The CPU 23 is controlled by programs stored in a memory 24 .

As shown in FIG. 2, the laser control circuit 51 includes a switch 60 , a variable current source 61 for setting a reproduction light amount, a CR filter 62 , consisting of a resistor R 1 and a capacitor C 1 , amplifier A 1 and A 2 , a low pass filter (TPF) 63 , a driver 64 , a pulse shaper circuit 65 , a recording light amount adjusting circuit 66, and a driver 67 .

The switch 60 is changed over as a function of a switching signal coming from the CPU 23 if a laser beam is to be emitted from the laser diode 9 in accordance with a quantity of reproduction light.

The variable current source 61 generates a current that causes the laser diode 9 to emit a laser beam with a quantity of light that corresponds to the property of the optical disc 1 .

The CR filter 62 separates a monitor current IM for the photodiode PD into a high-frequency current IMH and a low-frequency current IML. The high and low frequency currents IMH and IML from the CR filter 62 are given to a node B and an amplifier A 1, respectively.

The amplifier A 1 amplifies the low-frequency current IML supplied by the CR filter 62 . The current amplified by the amplifier A 1 is given to the node B via a resistor R 2 .

At the node B, the current obtained by amplifying the low-frequency current IML performed by the amplifier A 1 and the high-frequency current IMH supplied by the CR filter 62 are added together. The sum current is then fed to amplifier A 2 .

The amplifier A 2 is a current-voltage converter for converting the sum current obtained at the node B into a voltage value. The voltage value supplied by the amplifier A 2 is fed to a low-pass filter 63 .

The low-pass filter 63 cuts off high-frequency components of interest in order to prevent an unstable state of the circuit, e.g. B. to avoid swinging. An output signal of the low-pass filter 63 passes through the switch 60 to the driver 64 .

The driver 64 causes the laser diode 9 to emit reproduction light corresponding to the voltage value supplied.

The pulse shaping circuit 65 sets the pulse width of a recording pulse (original signal) which comes from the recording signal shaping circuit 34 , depending on the characteristics of the optical disk 1 and the output characteristic of the laser diode 9 .

The recording light amount setting circuit 66 sets a voltage by which the laser diode 9 is caused to emit a laser beam with a recording light amount corresponding to the characteristic of the optical disk 1 . The voltage value of the recording light quantity setting circuit 66 can be changed in accordance with a recording light quantity switching signal coming from the CPU 23 .

The driver 67 causes the laser diode 9 to emit a laser beam with an amount of recording light corresponding to the voltage value supplied.

With this configuration, during playback operation, the switch 60 is turned on in response to a switching signal coming from the CPU 23 , and a feedback loop of the laser diode 9 is turned on based on the monitor light.

Consequently, the monitor current IM supplied by the photodiode PD in accordance with the laser beam emitted by the laser diode 9 is separated into the high-frequency current IMH and the low-frequency current IML, the separation being carried out by the CR filter 62 . The low-frequency current IML is amplified by the amplifier A 1 and is then added to the high-frequency current IMH at the node B.

The total current is converted by the amplifier A 2 into a voltage value which is to be supplied to the driver 64 via the low-pass filter 63 and the switch 60 . As a result, the driver 64 causes the laser diode 9 to emit reproduction light corresponding to the voltage value supplied.

In the circuit explained above, a servo system is ge forms in which a low-frequency component a has greater gain than a high-frequency compo nente.

As a result, sufficient reinforcement (which never frequency component) with regard to large changes in the threshold current corresponding to the temperature characteristic ensure the laser diode and you can make a correction Perform processing to find a suitable loop ver strengthening with regard to the returning light disturbances (high-frequency component) due to changes guarantee.

Furthermore, the low-pass filter 63 is inserted in order to separate unnecessary high-frequency components and an unstable condition, e.g. B. a swing of the circuit to avoid the.

In the circuit of Fig. 2, the laser diode 9 can be stably control so as for a constant output power. B. has a playback performance or an erasing performance.

As shown in FIG. 3, the pulse shaping circuit 65 includes a variable current source 71 , a variable resistor VR 1 , switches 72 and 74 , inverter circuits (inverters) 73 and 75 , a capacitor C 2 and an AND circuit 76 .

The variable current source 71 selects a current according to the required setting of the pulse width.

The switches 72 and 74 are switched on or off in accordance with a recording pulse supplied as a control signal, the recording signal coming from the circuit 34 . The switch 72 is turned on when the control signal is high, it is turned off when the control signal is low.

The switch 74 is operated in accordance with the control signal inverted by the inverter circuit 73 . The switch 74 is turned on when the control signal is low, it is turned off when it is high (the switches 72 and 74 are always in opposite states).

If e.g. For example, when the recording pulse shown in FIG. 4A changes from low to high level, switch 72 is turned on while switch 74 is turned off. Subsequently, a current coming from the variable current source 71 flows into the capacitor C 2 to increase the potential. As a result, the potential at node P increases as shown in Fig. 4B.

When the potential at node P exceeds a predetermined threshold, the potential at the output terminal of inverter circuit 75 changes from high to low as shown in Fig. 4C. The output signal of the AND circuit 76 is set at a high level when both the recording pulse from the recording signal shaping circuit 34 and the output signal of the inverter circuit 75 are set at a high level, as shown in Fig. 4D.

By changing the current strength of the variable current source 71 , the gradient of the potential increase at the node P changes.

When the recording pulse from the recording signal shaping circuit 34 is set to the low level, the switch 72 is turned off and the switch 74 is turned on. As a result, the potential at node P goes low and the output of AND circuit 76 goes low.

In this circuit arrangement, the pulse shaping (a setting) can be carried out by the current intensity of the variable current source 71 being switched selectively.

A variable circuit in the variable current source 71 will now be explained with reference to FIG. 5. The variable current source 71 is a current source formed by transistors 81 ₁ to 81 _n . Switches S 2 are connected to the emitters of transistors 81 ₂ to 81 _n . When one of the switches 82 is turned on, a corresponding transistor of the transistors 81 ₂ to 81 _{n is} actuated.

The switches 82 form a multiplexer 83 . The switches 82 are switched on / off in that the multiplexer 82 is electrically actuated so as to control a current I.

By using the variable current source 71 with such a structure in the pulse shaping circuit 65 shown in FIG. 3, a reference current is determined by an adjustment process of a variable resistor VR 2 . Then the pulse width can be set freely by actuating the multiplexer 83 .

However, in order to carry out the variable change of the pulse width with high precision, the characteristics of the respective transistors of the variable current source 71 must be mutually adapted. By executing the pulse shaper circuit 65 as a large integrated circuit (LSI circuit), the circuit described above can be well implemented in practice.

Next, a control band of the laser output power and a data signal band will be explained. If the band of control of the laser beam output power of the laser diode 9 is expanded, the output power of the laser beam of the laser diode 9 can be stabilized, and disturbances due to returning light can be reduced. Returning light disturbances appear specifically as noise of a playback data signal and a control signal (the focus / tracking signal).

When broadband control of a laser beam emitted from the laser diode 9 is performed, although the signal-to-noise ratio in the control band is increased, the signal-to-noise ratio outside the control band is reduced.

For this reason, to increase the signal-to-noise ratio of the playback and control signals by broadband control of the laser beam output power of the laser diode 9, the control band must be extended to the bands of the playback and control signals, or beyond.

If the preamplifier circuit 52 of the reproduction data signals and the laser control circuit 51 are integrated in a large-scale integrated circuit (LSI circuit) 53 , this LSI circuit 53 can be arranged on the optical head 3 or in the vicinity thereof.

With such a discrete circuit arrangement realize a short wiring, the bandwidth of the Overall circuit can be expanded, and the stability of the Circuit can be improved, and in this way implemented a circuit with a high signal-to-noise ratio. Furthermore, the size of the device can be reduced further.

The band of the entire circuit can be expanded and the stability can be improved by integrating the pre-amplification circuit 52 for playback data signals and the laser control circuit 51 in a large-scale integrated circuit (LSI) 52 and actuators for controlling a laser beam, a recording pulse width , the balance and the like on the optical head 3 or in the vicinity thereof together with the LSI circuit 53 .

When circuits with different functions or the masses inside the LSI circuit 53 with high and low power circuits are separated from each other, the respective circuits can be stabilized and mutual interference of the circuits can be avoided.

Furthermore, if circuits with different functions or the voltage sources inside the LSI circuit 53 with circuits of large and small power are separated from one another, the respective circuits can be stabilized, and mutual interference between the circuits can be avoided.

In addition, when circuits with different functions or portions where changes in high currents and changes in small currents occur in the LSI circuit 53 have the large and small power circuits which are separated from each other, reference voltage sources become for each Circuit systems formed in different circuits, and these respective circuits can be stabilized, whereby a mutual interference of the circuits can be avoided.

In addition, if the laser diode 9 and the photodiode PD are separated from one another, a blocking voltage of the photodiode PD can be selected practically arbitrarily. Therefore, the photodiode PD can be freely selected, the blocking voltage of the photodiode PD being freely selectable regardless of the driving voltage of the laser diode 9 .

Claims (6)

A disk drive for optical disks ( 1 ) for recording data onto and / or reading data from an optical disk ( 1 ), comprising:

• a) a laser beam source ( 9 ) for generating a laser beam;
• b) a converter device ( 8 ) for photoelectrically converting a laser beam emitted by the laser beam source ( 9 ) and reflected by the optical plate ( 1 ) into an electrical current (IM);
• c) an output device (PD) for outputting an electrical current (IM) corresponding to an intensity of the laser beam emitted by the laser beam source ( 9 ), the electrical current (IM) containing high-frequency and low-frequency components (IML, IMH);
• d1) a recording device ( 34, 51 ) for recording data on the optical disc ( 1 ) by causing the laser beam source ( 9 ) to generate the laser beam in accordance with recording data, and / or
• d2) reading means ( 19 , 52 ) for reading data recorded on the optical disc ( 1 ) using the current (IM) obtained from the photoelectric conversion device ( 8 ); characterized by ,
• e) a separating device ( 62 ) which separates the current (IM) supplied by the output device (BD) into the high-frequency component (IMH) and the low-frequency component (IML).
• f) an amplifier device (A 1 ) for amplifying the low-frequency component (IML);
• g) an adding device (B) for adding the low-frequency component (IML) amplified by the amplifier device (A 1 ) to the high-frequency component (IMH) in order to obtain a sum of the high-frequency and low-frequency components.
• h) a converter device (A 2 ) for converting the sum of low and high frequency components (IML, IMH) into a voltage; and
• i) a stabilizing device ( 63 , 64 ) for stabilizing the intensity of the laser beam emitted by the laser beam source ( 9 ) in accordance with the voltage output by the converter device (A 2 ).

2. Disk drive according to claim 1, characterized in that at least one device or some devices of the separating device ( 62 ), the amplifier device (A 1 ), the adding device (B), the converter device (A 2 ) and the stabilizing device ( 63 , 64 ) are highly integrated. 3. Disk drive according to claim 1 or 2, characterized in that the separating device ( 62 ) has a CR filter ( 62 ) formed from a capacitor (C 1 ) and a resistor (R 1 ). 4. Disk drive according to one of claims 1 to 3, characterized in that the stabilizing device ( 63 , 64 ) a low-pass filter ( 63 ) for cutting off unnecessary high-frequency components (IMH) from the voltage obtained from the converter device (A 2 ) and a driver ( 64 ) which causes the laser beam source ( 9 ) to generate a laser beam in accordance with a voltage value supplied by the low-pass filter ( 63 ). 5. Disk drive according to claim 1, characterized ge indicates that the detector device (PD) has a photodiode.   6. Disk drive according to one of claims 1 to 5, characterized in that the laser beam source ( 9 ) contains a semiconductor laser oscillator.