JP4103242B2 - Light output control device and recording medium driving device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a light output control device that controls the output of a light source that emits light.And recording medium driving apparatusIn particular, the light output control device suitable for controlling the output of the light source for data recording and / or reproduction provided in the optical pickup deviceAnd recording medium driving apparatusAbout.
[0002]
[Prior art]
2. Description of the Related Art In recent years, an optical disk capable of recording and reproducing information with a laser beam has been actively developed as a recording medium that meets the demand for an increase in the amount of information and recording and reproduction with high density and high speed. Yes. The recordable optical disc includes a write-once type that can be recorded only once and a rewritable type that can be recorded and erased any number of times.
[0003]
The write-once optical disc is focused and information is written on a guide groove formed on a substrate by a laser (pits are formed), and information can be recorded only once. In addition, the rewritable optical disk includes a magneto-optical disk using a magneto-optical effect and a phase-change optical disk using a reversible crystal state change. In the case of a phase-change optical disk, external magnetism is not required and laser light is used. Recording and erasing are possible only by power modulation.
[0004]
As shown in FIG. 16A, a recording apparatus for writing information on such a write once or phase change type optical disc has, for example, a reproduction laser power for detecting a position and a reproduction laser power higher than this reproduction laser power. Information is recorded with two output levels of laser power such as a recording laser power for recording information at a high level. For example, in a phase change optical disc, data is recorded (pits are formed) by making the recording layer amorphous by laser power of a recording level that is higher than the reproduction level. In order to stabilize the light amount of the laser beam, the recording apparatus uses each level of the laser beam for recording and reproduction by a sampling signal generated at a predetermined timing as shown in (B) and (C) of FIG. The laser driver is fed back to each control so that each level becomes constant, and the two output levels are made constant.
[0005]
FIG. 17 shows a configuration example of a conventional light output control device that controls the output of a light source in such a recording apparatus. In this conventional light output control device, the output from the light detector 302 that receives the light emitted from the light source 301 is amplified by the amplifier 303 and input to the sample hold circuits 304 and 305 that sample the recording level and the reproduction level. The
[0006]
In the sample hold circuit 304, a sampling pulse (Read sample pulse) is generated at a predetermined timing, and thereby the reproduction level is sampled. Then, the reproduction level sampled and held by the sample hold circuit 304 is subtracted by a predetermined reference signal determined in advance and a subtractor 306 at the subsequent stage. The output of the subtractor 306 is amplified by the amplifier 308 and input to the variable current source 310. The variable current source 310 is controlled so that the laser power of the light source 301 is optimized in accordance with the output of the amplifier 308. Therefore, the laser power of the reproduction level is controlled by the variable current source 310. Will be.
[0007]
Similarly, the sample hold circuit 305 generates a sampling pulse (Write sample pulse) at a predetermined timing, thereby sampling the recording level. Then, the recording level sampled and held by the sample and hold circuit 305 is subtracted from a predetermined reference signal determined in advance by a subtractor 307 in the subsequent stage. The output from the subtractor 307 is amplified by the amplifier 309 and input to the variable current source 311. The variable current source 311 changes the laser power of the light source 301 in accordance with the output of the amplifier 309. Therefore, in the light source 301, the laser power at the recording level is controlled by the variable current source 311. .
[0008]
Such a conventional light output control device samples the recording level and the reproduction level and compares them with a predetermined reference signal to control the laser power of the recording level and the reproduction level.
[0009]
In addition, as shown in FIG. 18, data writing, that is, formation of pits is often performed by a so-called pulse train as shown in FIG. 18. In this case, the pulses are subdivided.
[0010]
[Problems to be solved by the invention]
By the way, when data is to be recorded at high speed, it is necessary to narrow the output time of the recording level and the reproduction level, that is, the generation interval of signals of each level. As described above, in order to control the laser power of the recording level and the reproduction level, sampling by the sampling pulse is required for each level. However, when data is recorded at a high speed such as 50 Mbps or 100 Mbps, sampling is performed. Becomes difficult. This makes it impossible to control the laser power for each level.
[0011]
In addition, when forming pits conventionally, so-called DC-free, in which the pit formation ratio is constant, is employed. In this case, the output level is compared with a predetermined (constant) reference signal. Although the laser power is controlled based on the detection result, it may be recorded that data is not DC-free. In the case of recording data that is not DC-free, the output level cannot be controlled by comparison using a constant reference signal. For this reason, it is conceivable to control the output level based on a reference signal generated by appropriately sampling a recording pulse for driving the light source, but data is recorded by a pulse as in the above-described pulse train ( In the case of forming one pit), it is necessary to sample each pulse, and when the pulse is subdivided, sampling becomes difficult.
[0012]
  Accordingly, the present invention has been made in view of the above-described circumstances, and is a light output control device capable of accurately controlling the output of a light source even when data is recorded or reproduced at high speed.And recording medium driving apparatusThe purpose is to provide.
[0013]
[Means for Solving the Problems]
  In order to solve the above-described problems, a light output control device according to the present invention includes a light source that emits light for recording and / or reproducing data on a signal recording medium, a signal for writing data, and / or Alternatively, a drive current switching unit that switches a current value to be supplied to the light source based on a readout signal, a light detection unit that detects a light amount emitted from the light source, and outputs a light detection signal corresponding to the detected light amount, and a light source drive signal A first low-pass filter for smoothing, a second low-pass filter for smoothing the light detection signal, a signal smoothed by the first low-pass filter, and a second low-pass filter First difference signal calculation means for calculating a difference signal from the smoothed signal, and variable current means for controlling the current value of the drive current according to the difference signal are provided.The first and second low-pass filters can be switched to a plurality of signal pass bands, and the first and second low-pass filters have a high signal pass band at the start of data recording. Is switched to a low signal passband after a predetermined time has elapsed since the start of data recording..
  In order to solve the above-described problems, the light output control device according to the present invention includes a light source that emits light for recording and / or reproducing data on a signal recording medium, and a signal for writing data. And / or a drive current switching unit that switches a current value supplied to the light source based on the readout signal, a light detection unit that detects a light amount emitted from the light source and outputs a light detection signal according to the detected light amount, and a light source drive A first low-pass filter for smoothing the signal; a second low-pass filter for smoothing the photodetection signal; a signal smoothed by the first low-pass filter; and a second low-pass filter A first difference signal calculating means for calculating a difference signal from the signal smoothed by the filter; and a variable current means for controlling the current value of the drive current in accordance with the difference signal. The low pass filter The signal pass band being can be switched, when the access to the inner periphery of the disc-shaped the signal recording medium is a high signal passband.
  In order to solve the above-described problems, the light output control device according to the present invention includes a light source that emits light for recording and / or reproducing data on a signal recording medium, and a signal for writing data. And / or a drive current switching unit that switches a current value supplied to the light source based on the readout signal, a light detection unit that detects a light amount emitted from the light source and outputs a light detection signal according to the detected light amount, and a light source drive A first low-pass filter for smoothing the signal; a second low-pass filter for smoothing the photodetection signal; a signal smoothed by the first low-pass filter; and a second low-pass filter A first difference signal calculating means for calculating a difference signal from the signal smoothed by the filter; and a variable current means for controlling the current value of the drive current in accordance with the difference signal. Of light emitted from the light source Serial a signal recording return light beam detecting means for detecting the return light reflected by the medium, subtracting a reference value based on the write characteristics of the data to the signal recording medium from said difference signal.
  Furthermore, the recording medium driving device according to the present invention includes a light output control unit having the structure of the light output control device as described above.
[0014]
The light output control device having such a configuration includes a first differential signal from a light detection signal smoothed by the first low-pass filter and a light detection signal smoothed by the second low-pass filter. The variable current means controls the current value of the drive current supplied to the light source in accordance with the difference signal calculated by the calculation means.
[0015]
  In order to solve the above-described problems, the light output control device according to the present invention is based on a light source that emits light for recording and / or reproducing data on a signal recording medium, and a writing signal. Driving current switching means for switching the driving current to the light source between the first current value and the second current value, and light detection for detecting a light amount emitted from the light source and outputting a light detection signal corresponding to the detected light amount Means for detecting a read signal component in the light detection signal and outputting a detection read signal; and detecting a write signal component from a difference between the light detection signal and the detection read signal. Second signal detecting means for outputting a detection write signal, a first low-pass filter for smoothing the detection write signal, a signal smoothed by the first low-pass filter, and a predetermined reference With write signal A first difference signal calculating means for calculating a minute signal and outputting a write difference signal; and a second difference for calculating a difference signal between the detection read signal and a predetermined reference read signal and outputting the read difference signal. A signal calculating means; a first variable current means for controlling the first current value of the drive current in accordance with the write differential signal; and a second variable for controlling the second current value of the drive current in accordance with the read differential signal. Variable current means.
  Furthermore, a recording medium driving device according to the present invention includes a light output control unit having the structure of the light output control device.
[0016]
The light output control device having such a configuration detects the read signal component and the write signal component from the light detection signal by the first signal detection unit and the second signal detection unit, and detects and reads the signal component. And a detection write signal. Then, the light output control device performs the first operation according to the write difference signal calculated by the first difference signal calculation means from the detection write signal smoothed by the first low-pass filter and the predetermined reference write signal. The first variable current means controls the first current value of the drive current, and the first variable current means outputs the first current value according to the read difference signal calculated by the second difference signal calculation means from the detection read signal and the predetermined reference read signal. Two variable current means control the second current value of the drive current.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0018]
First, as shown in FIG. 1, a light output control device according to a first embodiment includes a light source 2 that emits light for recording and / or reproducing data on a disk that is a signal recording medium. The switch unit 19 which is a drive current switching means for switching the current value of the drive current supplied to the light source 2 based on the data writing signal or the reproduction signal, and the emitted light amount of the light source 2 are detected, and the detected light amount An output light detector 4 that is a light detection means for outputting a light detection signal, a low-pass filter 14 that is a first low-pass filter for smoothing a data writing signal and / or a reproduction signal, A low-pass filter 13 that is a second low-pass filter that smoothes the detection signal, and a difference signal between the signal smoothed by the low-pass filter 14 and the signal smoothed by the low-pass filter 13 A first subtractor 16 is a difference signal calculating means for calculating, and a variable current source 18 is a variable current means for controlling the current value of the driving current in accordance with the difference signal.
[0019]
The light output control device 11 is configured to receive the light emitted from the light source 2 by the emitted light photodetector 4, and to control the laser power of the light source 2 based on the amount of the received light. For example, FIG. It is possible to control the output of the light source 2 provided in the optical pickup device 1 having the configuration as shown in FIG.
[0020]
Here, the optical pickup device 2 shown in FIG. 2 performs recording and / or reproduction of data by irradiating the disk 200 with light, and includes a light source 2 that emits light and light emitted from the light source 2. A beam splitter 3 that reflects the reflected light to the emitted light detector 4 that detects the emitted light, and transmits the emitted light from the light source 2 that has been transmitted by the beam splitter 3 toward the objective lens 6, The beam splitter 5 that reflects the return light from the disk 200 to the return light detector 7 and the light emitted from the light source 2 transmitted from the beam splitter 5 converge on the signal recording surface of the disk 200 and And an objective lens 6 that transmits the return light from 200 to the beam splitter 5.
[0021]
Here, for example, the disc 200 is focused and information is written on a guide groove formed on the substrate by a laser (pits are formed), and information can be recorded only once. The phase change optical disk utilizes a write-once type or reversible crystal state change.
[0022]
The light source 2 is, for example, a laser light source that emits laser light. Usually, the laser power applied to the disc 200 is different when recording data (when forming pits on the disc 200) and when reproducing data (when reading pits formed on the disc 200). In the light source 2, the laser power is controlled by the light output controller 11 for the reproduction level and the recording level that is higher than the reproduction level.
[0023]
  Specifically, the light source 2 is a laser for each of the recording level and the reproduction level based on a write signal for forming a pit on the disc 200 and a reproduction signal for reading the pit formed on the disc 200. The power is switched, and for recording, for example, the light source 2 at the recording level is pulse-driven based on a pulsed data write signal as shown in FIG. Further, the reproduction is usually controlled so that the laser power at the reproduction level of the light source 2 becomes substantially constant by a signal having a constant value. The emitted light emitted from the light source 2 isBeam splitter 3Is incident on.
[0024]
The beam splitter 3 transmits the outgoing light from the light source 2 to the other beam splitter 5 and reflects it toward the outgoing light detector 4.
[0025]
The emitted light photodetector 4 is a photodetector that directly receives the emitted light from the light source 2 and outputs a light detection signal according to the intensity of the received light. For example, at the time of recording, the emitted light photodetector 4 outputs a signal as shown in FIG. 3B as a light detection signal. The emitted light light detector 4 constitutes a part of the light output control device 11.
[0026]
The beam splitter 5 transmits the light emitted from the beam splitter 3 to the objective lens 6 or emits the return light from the disk 200 to the return light photodetector 7.
[0027]
The objective lens 6 converges the outgoing light transmitted through the beam splitter 5 on the signal recording layer of the disk 200. The light incident on the disk 200 is reflected by the signal recording layer, becomes return light, enters the beam splitter 5 through the objective lens 6, and is reflected by the return light photodetector 7.
[0028]
The return light light detector 7 is a light detector that receives the return light from the disk 200, and outputs a light detection signal according to the intensity of the received light. For example, the return light detector 7 outputs a substantially pulse signal as shown in FIG. 3B as a light detection signal, for example, according to the amount of received return light. The return light light detector 7 constitutes a part of the light output control device 11. However, the light detection signal output from the return light light detector 7 can be used as servo information in a servo signal processing unit (not shown). Used.
[0029]
The optical pickup device 1 having such a configuration records data (forms pits) on the disc 200 in accordance with a data write signal, or information recorded on the disc 200 by a data reproduction signal. A signal (formed pit) can be reproduced.
[0030]
The light output control device 11 that controls the laser power of the light source 2 of the optical pickup device 1 configured as described above includes an amplifier 12, low-pass filters 13, 14, in addition to the light source 2 and the emitted light photodetector 4. A multiplier 15, a subtracter 16, an amplifier 17, a variable current generator 18, and a switch unit 19 are provided.
[0031]
Hereinafter, each part of the light output control device 11 will be specifically described along a signal processing procedure.
[0032]
  When recording or reproducing data to or from the disk 200,3As shown in the middle (A), the laser power of the light source 2 is controlled in accordance with a data writing signal or reproducing signal composed of a pulse train. In the light output control device 11, the data writing signal or reproducing signal is input to the switch unit 19 and the low-pass filter 14.
[0033]
The switch unit 19 is configured by a switch for turning on / off the connection between the variable current source 19 and the light source 2, and switches the switch according to the input signal. Specifically, at the time of recording, the switch unit 19 switches the laser power of the light source 2 by turning on / off the connection of the variable current source 8 to the light source 2 by the switch according to the input pulse train. . The outgoing light from the light source 2 is incident on the outgoing light photodetector 4. Note that when data is recorded at a high density (to form pits), it is necessary to perform switching at high speed, so that the switch unit 19 is capable of high-speed switching.
[0034]
The emitted light detector 4 outputs a light detection signal corresponding to the amount of light emitted from the light source 2, and this signal is amplified by the amplifier 12 and input to the low-pass filter 13. Here, the amplifier 12 is, for example, an I / V converter.
[0035]
The low-pass filter 13 performs a process of removing a high frequency component of the photodetection signal input via the amplifier 12, that is, a process of smoothing. That is, the light detection signal is output to the subsequent processing unit by the low-pass filter 13 with an average value including fluctuations. For example, a photodetection signal (solid line) input as a substantially pulse signal as shown in FIG. 4B is output as a signal (solid line) as shown in FIG. Then, the signal processed by the low pass filter 13 is input to the subtractor 16.
[0036]
Here, the signal pass band of the low-pass filter 13 is set sufficiently lower than the signal band processed by the data writing signal or reproducing signal, the emitted light photodetector 4, and the amplifier 12. Thereby, the control speed of the laser power of the light source 2, that is, the response of the control system depends on the low-pass filter 13.
[0037]
On the other hand, the low-pass filter 14 to which the same data writing signal or reproducing signal as that inputted to the switch unit 19 is inputted, removes the high frequency component of the data writing signal or reproducing signal (smoothing). Process). For example, even if the signal for writing data is a signal for forming one pit by a subdivided pulse train, the low-pass filter 14 can obtain a smoothed signal from which a high frequency component has been removed as a downstream signal. Output to the processing unit. Specifically, a signal composed of a pulse train as shown in FIG. 4A is output as a signal (solid line) as shown in FIG. The signal processed by the low pass filter 14 is input to the multiplier 15. The signal pass band of the low-pass filter 14 is the same as the signal pass band of the low-pass filter 13 described above.
[0038]
The multiplier 15 multiplies the signal output from the low-pass filter 14 by a coefficient K, and the multiplied signal is input to the subtractor 16. Here, the coefficient K is a value determined in advance.
[0039]
  The subtracter 16 subtracts the signals processed in the low-pass filter 13 and the low-pass filter 14 and outputs a signal composed of the difference by subtraction. That is, the subtractor 16 allows a low-pass filter.13Detection signal and low-pass filter smoothed in14The difference between the smoothed data write signal and the reproduction signal is obtained.
[0040]
  Therefore, the subtracter 16 emits the data write signal or reproduction signal for actual data recording or reproduction and the light source 2 whose laser power is controlled by the data write signal or reproduction signal. Since the difference from the light detection signal based on the amount of light is taken, this is the case where data that is not DC-free is recorded.EvenThe change in the photodetection signal is monitored using a signal for recording or reproducing actual data as a reference signal.
[0041]
In addition, since the low-pass filter is used, even if the write signal signal is for recording data by a series of pulses (forming one pit), the reference signal is not required to be sampled for each pulse. Based on this reference signal, the photodetection signal is monitored. Further, similarly for the light detection signal, the amount of light emitted from the pulsed light source 2 can be regarded as a smoothed light detection signal.
[0042]
The signal output from the subtractor 16 is amplified by the amplifier 17 and input to the variable current source 18.
[0043]
The variable current source 18 controls the current value supplied to the light source 2 in accordance with the output from the amplifier 17. As described above, the signal input to the amplifier 17 is a signal composed of the difference between the light detection signal corresponding to the amount of light emitted from the light source 2 and the data writing signal or the reproduction signal. When the value is smaller, the current value of the current supplied from the variable current source 18 to the light source 2 is increased according to the difference value.
[0044]
The light output control device 11 having the above-described configuration, when performing recording or reproduction of data on or from the disk 200, the light detection signal from the emitted light light detector 4 obtained through the low-pass filter 13 and the low-pass filter 14. By comparing the signal (writing signal or reproducing signal) for controlling the laser power of the light source 2 obtained via the feedback and applying the feedback, an appropriate amount of emitted light can be obtained at the recording level or reproducing level. The laser power of the light source 2 is controlled.
[0045]
That is, the light output control device 11 matches the light detection signal according to the amount of light emitted from the light source 2 obtained through the low-pass filter 13 with the data write signal obtained through the low-pass filter 14. The laser power is controlled. The coefficient K of the multiplier 15 is determined in advance as a value that enables such a fitting process. For example, by multiplying by the coefficient K, the values of the signals shown in (B) to (D) in FIG. 4 increase as shown by the dotted line in FIG.
[0046]
The case where the amount of light emitted from the light source 2 does not reach a predetermined amount will be described in detail. The difference between the output signal of the low-pass filter 13 and the output signal of the low-pass filter 14 increases, and the signal level output from the subtractor 16 Becomes larger. The variable current source 18 changes the current value of the current supplied to the light source 2 based on the output output from the subtractor 16 and amplified by the amplifier 17, so that the light source 2 does not reach the predetermined amount of emitted light. The output is increased according to the difference signal obtained in the subtractor 16. With this increase in output, the amount of light emitted from the light source 2 becomes the optimum amount of light for recording or reproducing data. For example, when the light source 2 is not set to a predetermined amount of emitted light, a desired pit cannot be formed on the disc 200, and this is prevented.
[0047]
Further, as described above, the subtractor 16 combines the data write signal with the write signal component of the light detection signal, so that the light source 2 can be used even when the data write signal is not DC-free. Laser power can be accurately controlled.
[0048]
Further, since the light output control device 11 compares the data writing signal or reproducing signal with the light detection signal through the low-pass filter, the data writing signal or reproducing signal and the light detection signal are compared. Is not required to be sampled by the sampling pulse, and can be regarded as an averaged variation of the signals, that is, a slow variation. Thereby, even when data is recorded by a pulse train segmented for high-density recording, the laser power of the light source 2 can be controlled without requiring high-speed processing. For example, (A) in FIG. 5 shows a signal composed of a fine pulse train as compared with (B) in FIG. 4. This is a signal for writing data when the recording density is increased, for example. The detection positions of the signals (A) to (D) in FIG. 5 correspond to the detection positions of the signals (A) to (D) in FIG. Even when the recording density is increased in this way, the laser power of the light source 2 can be accurately controlled without requiring high-speed processing by comparing the signals through the low-pass filter.
[0049]
Therefore, even when a data recording method in which one pit is formed by a subdivided pulse train is adopted, the laser of the light source 2 is not required to perform high-speed processing by passing a data write signal through a low-pass filter. Power can be controlled.
[0050]
Next, a second embodiment will be described. The light output control device 21 shown in FIG. 6 as the second embodiment controls the laser power of the light source 2 based on two different output levels, a low output level and a high output level. Specifically, the light output control device 21 controls the laser power of the light source 2 for writing data by a signal in which the output level for data writing is added to the output level at the time of reproduction. The laser power of the light source 2 is controlled based on the light detection signal in which the writing level is added to the reproduction level as shown in FIG. The optical pickup device 1 switches the laser power of the light source 2 separately as a writing level and a reproduction level, for example, writing data (pit formation) while reading address pits formed on the disk 200, for example. It is possible to do.
[0051]
The light output control device 21 includes an output light detector 4, amplifiers 22, 30, 33, a sample hold circuit 23, subtractors 24, 26, 29, low-pass filters 25, 27, a multiplier 28, a variable current source 24, and a switch. The unit 32 and the light source 2 are provided.
[0052]
The light output control device 21 is different from the light output control device 11 according to the first embodiment described above in that an amplifier 22 is a part that processes a signal output from the emitted light photodetector 4. A sample-and-hold circuit 23 and subtractors 24 and 26 are provided between the low-pass filter 25 and a variable current source 34 that controls a current supply to the light source 2 based on a signal level from the subtractor 26. It is.
[0053]
In the light output control device 21, the low-pass filter 27 and the switch unit 32 are input with a write signal composed of a pulse train in a signal for driving the light source 2. Specifically, a pulse train as shown in FIG. 8A is input.
[0054]
This pulse train is smoothed by the low-pass filter 27, then multiplied by the coefficient K in the multiplier 28, and output to the subtractor 29.
[0055]
In the switch unit 32, the switch is turned on / off based on the data write signal, and the current supply to the light source 2 is switched by the variable current source 31. The light source 2 is given a reproduction level laser power by the current supplied from the variable current source 34.
[0056]
Thus, the emitted light from the light source 2 whose laser power is controlled by the switch unit 32 is received by the emitted light detector 4, and the emitted light detector 4 detects the light detection signal according to the amount of received light. Is output.
[0057]
The light detection signal output from the emitted light light detector 4 is amplified by the amplifier 22 and input to the sample hold circuit 23 and the subtractor 24 arranged at the subsequent stage of the sample hold circuit 23.
[0058]
The sample hold circuit 23 detects a reproduction signal component in the light detection signal and outputs a detection reproduction signal. Specifically, as shown in FIG. 8G, the sample hold circuit 23 acquires a detection reproduction signal using a Read sample pulse input within a reproduction period in which no data is written as a trigger. . Then, the detection / reproduction signal acquired in this way is, for example, a signal as shown in (E) of FIG. 8 and is input to the subtractors 24 and 26 in the subsequent stage.
[0059]
The subtracter 24 also receives a photodetection signal output from the amplifier 22, for example, a photodetection signal in which a write signal component is added to a reproduction signal component as shown in FIG. The subtractor 24 calculates a write signal component (detection write signal) based on the difference between the light detection signal from the amplifier 22 and the detection reproduction signal obtained in the sample hold circuit 23. Specifically, the subtractor 24 calculates a detection write signal as shown in FIG. 8F as the difference between the signal shown in FIG. 8B and the signal shown in FIG. To do. The detection write signal obtained by the subtractor 24 is smoothed by the low-pass filter 25 and input to the subtractor 29.
[0060]
As described above, the signal obtained via the low-pass filter 27 and the multiplier 28 is also input to the subtractor 29, and the subtractor 29 calculates the difference between this signal and the signal from the low-pass filter 25. The signal obtained here is input to the variable current source 31 via the amplifier 30. Here, since a low-pass filter is used, even for a write signal composed of a pulse train, a difference from the detected write signal can be obtained using the detected write signal as a reference signal without having to sample each pulse. .
[0061]
The variable current source 31 changes the current value of the current supplied to the light source 2 on the basis of the difference signal obtained by the subtractor 29, similarly to the variable current source 18 of the light output control device 11 described above. As a result, the laser power at the recording level of the light source 2 is controlled based on the write signal component.
[0062]
On the other hand, the subtractor 26 outputs the difference between the detected reproduction signal output from the sample hold circuit 23 and the Read reference signal which is a predetermined reference reproduction signal. The Read reference signal is a signal having an optimum value for reproducing data. Therefore, for example, when the value of the detection reproduction signal obtained based on the light emitted from the light source 2 does not reach the value of the reference signal (Read reference signal) that is optimal for reproduction, subtraction is performed. The signal level output from the device 26 is a large value. The signal output from the subtractor 26 is input to the variable current source 34 via the amplifier 33.
[0063]
The variable current source 34 changes the current value of the current supplied to the light source 2 according to the level of the input signal. Here, since the variable current source 34 and the variable current source 31 are connected in parallel to the light source 2, an increase in the output of the variable current source 34 is transmitted as an increase in the laser power of the light source 2. As a result, the laser power at the reproduction level of the light source 2 is controlled by the current from the variable current source 34.
[0064]
The light output control device 21 having the above-described configuration can separately control the recording level and the reproduction level laser power of the light source 2. Specifically, with respect to the control of the laser power at the recording level, components that enable processing similar to the processing of the light output control device 11 described above, that is, the emitted light photodetector 4, the amplifier 22, and the sample hold circuit 23, the subtractor 24, the low-pass filters 25 and 27, the multiplier 28, and the subtractor 29. The laser power at the reproduction level is controlled by the outgoing light photodetector 4, the amplifier 22, the sample hold. The circuit 23 and the subtractor 26 are used.
[0065]
Since the light output control device 21 compares the write signal components via the low-pass filter 25 and the low-pass filter 27 as in the light output control device 11 of the first embodiment described above, for example, Even when the pulse generation interval of the write signal is shortened in order to record data at a high speed, the laser power at each of the recording level and the reproduction level can be accurately controlled. For example, even for a signal composed of a fine pulse train as shown in FIG. 9A, the laser power can be accurately set for each of the recording level and the reproduction level by comparing the signals through a low-pass filter. Note that the detection positions of the signals (A) to (F) in FIG. 9 correspond to the detection positions of the signals (A) to (F) in FIG.
[0066]
Next, a third embodiment will be described. In the first and second embodiments described above, the laser power of the light source 2 is controlled based on the light reception result of the emitted light detector 4, and the light output control according to the third embodiment is performed. As shown in FIG. 10, the apparatus controls the laser power of the light source 2 based on the light reception result in the return light photodetector 7.
[0067]
The light output control device 41 basically has the same configuration as that of the light output control device 11 of the first embodiment described above. The light output control device 41 outputs the light detection signal output from the return light light detector 7. Only the signal for controlling the light source 2 is different. Then, similarly to the light output control device 11, the light output control device 41 can control the laser power of the recording level or reproduction level of the light source 2.
[0068]
In the light output control device 41, as in the light output control device 11, a data write signal and a reproduction signal are input to the low-pass filter 44 and the switch unit 49.
[0069]
The pulse train input to the low-pass filter 44 is smoothed here, and then multiplied by the coefficient K in the multiplier 45 and input to the subtractor 46.
[0070]
The switch unit 49 controls the supply of current to the light source 2 by the variable current source 48 by turning on / off the switch based on the data writing signal or reproducing signal.
[0071]
Thus, the emitted light from the light source 2 whose output is controlled by the switch unit 48 is reflected by the disc 200 and received by the return light detector 7 as return light.
[0072]
The return light detector 7 outputs a light detection signal corresponding to the amount of return light. The light detection signal output from the return light light detector 7 is amplified by the amplifier 42 and input to the low-pass filter 43. The low-pass filter 43 smoothes the input signal, and the signal is smoothed. Is input to the subtractor 46.
[0073]
The subtractor 46 obtains the difference between the signal from the low pass filter 43 and the signal obtained via the low pass filter 44 and the multiplier 45, and the obtained signal is input to the subtractor 50.
[0074]
In the subtractor 50, subtraction is performed using a reference value. Here, the reference value is a value acquired in advance depending on the disc 200, such as data write characteristics to the disc 200. For example, in general, before recording or reproducing data, the recording / reproducing apparatus performs trial writing such as reading the written data and obtaining the data writing characteristics in advance after writing the data. The reference value is a write characteristic of data obtained at that time, for example, a characteristic that pits are difficult to form in the radial direction of the disk. Specifically, at the time of trial writing, the laser power of the light source 2 optimal for forming pits for each area divided in the radial direction of the disk, for example, the output value of the multiplier 45 is stored as a reference value. deep. In this way, by subtracting the signal from the subtractor 46 based on the reference value acquired for each region, it is possible to control the laser power of the light source 2 in consideration of the writing characteristics for each region. The value thus subtracted by the reference value (optimum value) is amplified by the amplifier 47 and input to the variable current source 48.
[0075]
Note that the trial writing as described above is performed on the trial writing area, but when actually recording or reproducing data, the data is moved from the trial writing area to the actual data recording area. By starting recording or reproduction, it is possible to absorb a transient change in the light detection signal and obtain a smoothed light detection signal output from the low-pass filter.
[0076]
The variable current source 48 changes the current value of the current supplied to the light source 2 on the basis of the difference signal obtained by the subtractor 29, similarly to the variable current source 18 of the light output control device 11 described above.
[0077]
The light output control device 11 having the above configuration can control the light source 2 based on the light reception result of the return light photodetector 7.
[0078]
By controlling the laser power of the light source 2 based on the output of the return light detector 7 in this way, it becomes possible to control the laser power of the light source 2 taking into account the influence of the sensitivity difference of the disk 200. In other words, the light output control device 41 can control the laser power of the light source 2 while monitoring the formation of pits recorded on the disc 200.
[0079]
For example, the reflectivity from the pit forming portion is usually changed by heat, and the amount of return light decreases with the passage of time. Therefore, in response to a data write signal as shown in FIG. Actually, a photodetection signal as shown in FIG. 11B is detected. Here, the shaded portion in the figure is the loss due to the change in reflectance. Even in such a case, since the laser power of the light source 2 is controlled based on the return light, the laser power of the light source 2 can be set to an optimum output for pit formation.
[0080]
Further, by controlling the laser power of the light source 2 based on the return light, it is possible to control the laser power of the light source 2 in consideration of the influence even when the disk 200 is tilted.
[0081]
Next, a fourth embodiment will be described. The light output control device 61 shown in FIG. 12, which is the fourth embodiment, is configured to control the laser power of the light source 2 based on a signal composed of a write signal and a predetermined reproduction signal. In the configuration of the light output control device 41 of the third embodiment described above, a reproduction signal component is obtained from the light detection signal of the emitted light photodetector 4, and the light source 2 of the light source 2 is obtained based on this reproduction signal component. A configuration for controlling the reproduction level laser power is also added. As a newly added configuration, an amplifier 62 that amplifies the light detection signal from the emitted light photodetector 4, a sample hold circuit 63 that detects a reproduction signal component from the light detection signal from the amplifier 62, and a sample hold circuit 63. A subtractor 64 that obtains a difference between a detected reproduction signal that is a reproduction signal component in the photodetection signal output from a predetermined reference reproduction signal (Read reference signal), and a signal output from the subtractor 64 And a variable current source 66 that changes the current value of the current supplied to the light source 2 in accordance with the output of the amplifier 65.
[0082]
The part for controlling the laser power of the reproduction level of the light source 2 based on the signal component for reproduction in the light detection signal of the emitted light light detector 4 is the output of the light output control device 21 of the second embodiment described above. The laser power of the light source 2 is controlled by a process similar to the process performed in the order of the incident light detector 4, the amplifier 22, the sample hold circuit 23, the subtractor 26, the amplifier 33, and the variable current source 34.
[0083]
As described above, the recording level is controlled based on the light detection signal of the return light light detector 7, while the reproduction level is controlled based on the reproduction signal component of the light detection signal of the outgoing light light detector 4. By controlling the recording level, the recording level can be controlled in consideration of the influence of the writing characteristics of the disc 200, and the reproduction level is considered in consideration of the influence of the temperature characteristics of the light source 2. Will be able to control.
[0084]
In addition, by controlling the laser power at the reproduction level of the light source 2 based on the detection result of the emitted light photodetector 4, the light source 2 runs away, for example, during abnormal operation or when the reflectance of the disk is abnormally low. Therefore, it is possible to prevent the laser power from becoming an abnormally high output level, and to prevent the destruction of the light source 2 and the signal recorded on the disk, thereby providing a highly reliable device. It becomes possible to do.
[0085]
Next, a fifth embodiment will be described. The light output control device 71 shown in FIG. 13 as the fifth embodiment is configured to control the laser power of the light source 2 based on a signal composed of a write signal and a predetermined reproduction signal. The light output control device 41 according to the second embodiment is incorporated into the light output control device 41 according to the third embodiment.
[0086]
The part corresponding to the above-described second embodiment will be described. The signal from the emitted light photodetector 4 is amplified by the amplifier 72 and is arranged at the subsequent stage of the sample hold circuit 73 and the sample hold circuit 73. Input to the subtractor 74.
[0087]
In the sample hold circuit 73, a read signal component in the photodetection signal is acquired by using the Read sample pulse as a trigger, and the thus obtained reproduction signal component is used as a detection reproduction signal as a subtracter 74, 76 is input.
[0088]
In the subtractor 74, the photodetection signal signal from the amplifier 72 is input. Therefore, here, the write signal component is detected from the difference between the photodetection signal and the detection reproduction signal.
[0089]
The write signal component obtained by the subtractor 74 in this way is used as a detection write signal and input to the low-pass filter 75, where it is smoothed and input to the subtractor 78.
[0090]
A data write signal is input to the subtractor 78 via the low-pass filter 44 and the multiplier 77, and a difference between this signal and the detection read-out signal from the low-pass filter 75 is obtained. The signal obtained here is multiplied by a coefficient K3 by a multiplier 79 and input to an adder 80.
[0091]
The adder 80 receives the signal from the subtractor 50, where it is added with the signal, amplified by the amplifier 47, and input to the variable current source 48. The variable current source 48 changes the current value of the current supplied to the light source 2 according to the level of the input signal.
[0092]
On the other hand, the subtractor 76 outputs a difference signal between the photodetection signal output from the sample hold circuit 73 and a Read reference signal which is a predetermined reference reproduction signal. The signal output from the subtractor 76 is input to the variable current source 82 via the amplifier 81. The variable current source 82 changes the current value of the current supplied to the light source 2 according to the level of the input signal.
[0093]
  The light output control device 71 having the above configuration adds the write signal component in the light detection signal of the return light light detector 7 and the write signal component in the light detection signal of the outgoing light light detector 4. The variable current source 48 for controlling the laser power at the recording level is controlled by the signal added by the device 80.PleaseTherefore, the recording level of the light source 2 can be stably controlled. For example, the control amount can be determined by the coefficient K3 of the multiplier 79, that is, whether the return light is dominant or the output light is dominant is determined by the coefficient K3 of the multiplier 79.
[0094]
In addition, the light output control device 71 is similar to the light output control device 61 of the fourth embodiment described above, on the basis of the reproduction signal component of the light detection signal of the emitted light light detector 4, and the reproduction level of the light source 2. Therefore, the laser power at this reproduction level can be controlled in accordance with the temperature characteristics of the light source 2.
[0095]
  The low-pass filter of the light output control device of the first to fifth embodiments can be switched to a plurality of signal pass bands, a high signal pass band is set at the start of data recording, and after a predetermined time has elapsed from the start of data recording. You may switch to a low signal pass band. Further, when accessing the inner and outer circumferences of the disk, a high signal pass band may be used. By switching the signal pass band of the low-pass filter in this way, access to the inner and outer circumferences of the disk is started when data recording starts.TheThe stability of output can be enhanced by switching to a low signal pass band after a predetermined time has elapsed from the start of data recording.
[0096]
The light output control device has been described above as the first to fifth embodiments. In the second, fourth, and fifth embodiments described above, the case where data is recorded based on a signal composed of a reproduction signal and a write signal added thereto is described. Also in the case of writing data while simultaneously performing the processing, the laser power of the light source 2 can be controlled for each of these output levels (recording level, reproduction level, and erasure level). FIG. 14 shows a signal output when data is written and an erasing process is simultaneously performed.
[0097]
For example, as a recording method for writing data while performing an erasing process, there is a method using a phase change optical disk using a reversible change in crystal state. In the recording method using the phase change optical disk, pits are formed by amorphization and erasure is performed by crystallizing the pits. In such a data recording method using a phase change optical disk, new data can be recorded while erasing past data that has already been recorded, with a laser power having an erasure level smaller than the recording level. .
[0098]
The pulse train shown in (B) of FIG. 14 shows the output of a necessary signal when data (pit length) as shown in (A) of FIG. 14 is to be formed.
[0099]
FIG. 15 shows a configuration example of the light output control device 90 configured to be applied when performing the erasing process.
[0100]
The light output control device 90 amplifies the light detection signal from the light detector 91 in the amplifier 92. The light detection signal amplified by the amplifier 92 is input to the sample and hold circuit 93, the subtractor 97 and the selector 94.
[0101]
The sample hold circuit 93 detects a cooling level in the light detection signal output from the amplifier 92. Specifically, the cooling level in the input light detection signal is detected by a cooling level sampling signal (cooling region pulse) as shown in FIG. Here, the cooling level is for setting the laser power at the end of the data (pit) to an output level lower than the erase level. By providing such an output level, the temperature at the end of the pit is set. It is possible to drastically reduce the change and suppress pit deterioration due to recrystallization. The cooling level detected by the sample and hold circuit 93 is input to subtractors 96 and 97 at the subsequent stage.
[0102]
The subtractor 97 calculates a difference signal between the light detection signal output from the amplifier 92 and the cooling level. That is, the subtractor 97 detects an erasing signal component and a writing signal component in the photodetection signal. Here, the signal calculated by the subtractor 97 is input to the selectors 99 and 104.
[0103]
The selector 99 detects a write signal component in the light detection signal. Specifically, the selector 99 detects a write signal component in the light detection signal by a recording gate (Write gate) signal as shown in FIG. Then, the write signal component in the light detection signal detected by the selector 99 is input to the low-pass filter 100.
[0104]
The low-pass filter 100 performs a process of smoothing the write signal component, and this smoothed signal and a write signal (in FIG. 14) that controls the laser power of the light source smoothed by the low-pass filter 101. The subtractor 102 calculates a difference from the signal obtained by smoothing the write signal as shown in (F). The signal calculated by the subtractor 102 is input to a variable current source for controlling the laser power of a light source (not shown) via the amplifier 103. Accordingly, the light source is controlled so that the laser power at the recording level is optimized based on a signal input to a variable current source (not shown).
[0105]
The laser power at the erasing level is controlled by the processing after the selector 104 by the same processing as the control of the laser power at the recording level. That is, in the selector 104, an erasing signal component in the photodetection signal is detected by an erasing gate (Erase gate) signal as shown in FIG. The erasure signal component in the light detection signal detected by the selector 104 is smoothed by the low-pass filter 105, and the smoothed signal and the laser of the light source 91 smoothed by the low-pass filter 106 are processed. A subtractor 107 calculates a difference from an erasing signal that is a signal for controlling power (a signal obtained by smoothing an erasing signal as shown in FIG. 14G). The signal calculated by the subtractor 107 is input to a variable current source for controlling the laser power of a light source (not shown) via an amplifier 108. Accordingly, the light source is controlled so that the laser power at the erasing level is optimized based on a signal input to a variable current source (not shown).
[0106]
The laser power at the reproduction level is controlled by the processing after the selector 94. That is, the selector 94 detects the signal component for reproduction in the photodetection signal by the reproduction gate (Read gate) signal. The detected reproduction signal component is input to the low pass filter 95.
[0107]
The low-pass filter 95 performs a process of smoothing the reproduction signal component of the light detection signal, and detects a difference from a predetermined reference reproduction signal. The difference signal is input to a variable current source for controlling the laser power of a light source (not shown) via an amplifier (not shown). Thus, the light source is controlled so that the laser power at the reproduction level is optimized based on a signal input to a variable current source (not shown).
[0108]
The cooling level is controlled as follows. In the subtractor 96, a difference signal between the cooling signal component of the photodetection signal output from the sample hold circuit 93 and the reference cooling signal having a predetermined bias value is calculated, and the calculated difference signal passes through the amplifier 98. To a variable current source for controlling the laser power of a light source (not shown). Thus, the cooling level of the light source is controlled based on a signal input to a variable current source (not shown).
[0109]
As described above, the light output control device 90 can control the output level of the light source 2 separately for the reproduction level, the recording level, and the erasing level even when writing data while simultaneously performing the erasing process. it can.
[0110]
【The invention's effect】
The light output control device according to the present invention supplies a light source that emits light for recording and / or reproducing data to a signal recording medium, and supplies the light source based on a signal for writing and / or reading data. Driving current switching means for switching the current value of the driving current to be detected, light detection means for detecting the light quantity emitted from the light source and outputting a light detection signal corresponding to the detected light quantity, and a first low level for smoothing the light source driving signal A pass filter, a second low pass filter for smoothing the light detection signal, a signal smoothed by the first low pass filter, and a signal smoothed by the second low pass filter Light that has been smoothed by the first low-pass filter by including first difference signal calculation means for calculating the difference signal of the first and second variable signal means for controlling the current value of the drive current in accordance with the difference signal. Detection signal and second The current value of the drive current supplied from the variable current means to the light source can be controlled according to the difference signal calculated by the first difference signal calculation means from the light detection signal smoothed by the low-pass filter. .
[0111]
As a result, the light output control device can accurately control the output from the light source even when data is recorded or reproduced at high speed.
[0112]
The light output control device according to the present invention includes a light source that emits light for recording and / or reproducing data on a signal recording medium, and a first drive current to the light source based on a write signal. Drive current switching means for switching between the current value and the second current value, light detection means for detecting a light quantity emitted from the light source and outputting a light detection signal corresponding to the detected light quantity, and reading in the light detection signal First signal detecting means for detecting a signal component for output and outputting a detection read signal; and a first signal detector for detecting a write signal component from a difference between the light detection signal and the detection read signal and outputting a detection write signal. 2 signal detection means, a first low-pass filter for smoothing the detection write signal, and a difference signal between the signal smoothed by the first low-pass filter and a predetermined reference write signal Then write difference A first differential signal calculating means for outputting a signal, a second differential signal calculating means for calculating a differential signal between the detection readout signal and a predetermined reference readout signal and outputting a readout differential signal, and a write differential signal By providing a first variable current means for controlling the first current value of the drive current in accordance with the second variable current means for controlling the second current value of the drive current in accordance with the read differential signal The first signal detection means and the second signal detection means detect a read signal component and a write signal component from the light detection signal, and output a detection read signal and a detection write signal, and In accordance with the write differential signal calculated by the first differential signal calculation means from the detection write signal smoothed by the first low-pass filter and the predetermined reference write signal, The current means controls the first current value of the drive current, and the second variable is determined according to the read differential signal calculated by the second differential signal calculating means from the detection read signal and the predetermined reference read signal. The current means can control the second current value of the drive current.
[0113]
As a result, the light output control device can accurately control the output from the light source even when data is recorded or reproduced at high speed. Even when the output of the light source is controlled by a signal composed of a write signal and a predetermined read signal, the write level and read level outputs of the light source can be controlled separately.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a light output control apparatus according to a first embodiment of the present invention.
FIG. 2 is a block diagram illustrating a configuration of an optical pickup device in which an output of a light source is controlled by a light output control device.
FIG. 3 is a diagram illustrating an example of a signal for writing data input to a light source and a light detection signal of the light source.
FIG. 4 is a diagram illustrating an input signal and an output signal of each unit of the light output control device according to the first embodiment.
FIG. 5 is a diagram illustrating an example of a case where an input signal and an output signal of each unit of the light output control device according to the first embodiment and a data write signal including a fine pulse train are input.
FIG. 6 is a block diagram showing a configuration of a light output control apparatus according to a second embodiment of the present invention.
FIG. 7 is a diagram illustrating an example of a light detection signal including a writing component and a reproducing component.
FIG. 8 is a diagram illustrating an input signal and an output signal of each unit of the light output control apparatus according to the second embodiment.
FIG. 9 is a diagram illustrating an example of a case where an input signal and an output signal of each unit of the light output control device according to the second embodiment are input as a data write signal including a fine pulse train.
FIG. 10 is a block diagram showing a configuration of a light output control apparatus according to a third embodiment of the present invention.
FIG. 11 is a diagram used to explain the loss of return light.
FIG. 12 is a block diagram showing a configuration of a light output control apparatus according to a fourth embodiment of the present invention.
FIG. 13 is a block diagram showing a configuration of a light output control apparatus according to a fifth embodiment of the present invention.
FIG. 14 is a diagram used for explaining a case where an erasing process is also performed based on a data write signal.
FIG. 15 is a block diagram showing a configuration of a light output control apparatus according to a sixth embodiment of the present invention.
FIG. 16 is a diagram used for explaining the case where the reproduction level and the recording level are detected based on the Reads sample signal and the Write sample signal.
FIG. 17 is a block diagram showing a configuration of a conventional light output control device.
FIG. 18 is a diagram used for explaining the case where pits are formed from fine pulses.
[Explanation of symbols]
2 light source, 4 outgoing light detector, 7 return light detector, 11 light output controller, 13, 14 low pass filter, 16 subtractor, 18 variable current source, 19 power switch, 21 light output controller, 23 Sample hold circuit, 24 subtractor, 25 low-pass filter, 26, 29 subtractor, 31 variable current source, 32 power switch, 34 variable current source

Claims (19)

A light source that emits light for recording and / or reproducing data on a signal recording medium;
Drive current switching means for switching a current value of a drive current supplied to the light source based on a data write signal and / or a read signal;
A light detecting means for detecting a light amount emitted from the light source and outputting a light detection signal corresponding to the detected light amount;
A first low-pass filter for smoothing the data write signal and / or read signal;
A second low pass filter for smoothing the photodetection signal;
First difference signal calculation means for calculating a difference signal between the signal smoothed by the first low-pass filter and the signal smoothed by the second low-pass filter;
Variable current means for controlling the current value of the drive current according to the difference signal,
The first and second low-pass filters can be switched to a plurality of signal pass bands,
Said first and second low-pass filter is a high signal passband at the start of recording of data, the light output characterized in that it is switched from the start of recording data to the low signal pass band after a predetermined time has elapsed Control device. A light source that emits light for recording and / or reproducing data on a signal recording medium;
Drive current switching means for switching a current value of a drive current supplied to the light source based on a data write signal and / or a read signal;
A light detecting means for detecting a light amount emitted from the light source and outputting a light detection signal corresponding to the detected light amount;
A first low-pass filter for smoothing the data write signal and / or read signal;
A second low pass filter for smoothing the photodetection signal;
First difference signal calculation means for calculating a difference signal between the signal smoothed by the first low-pass filter and the signal smoothed by the second low-pass filter;
Variable current means for controlling the current value of the drive current according to the difference signal,
The first and second low-pass filters can be switched to a plurality of signal pass bands,
When access to the inner periphery of the disc-shaped the signal recording medium, characterized in that it is a high signal pass band light output control device. A light source that emits light for recording and / or reproducing data on a signal recording medium;
Drive current switching means for switching a current value of a drive current supplied to the light source based on a data write signal and / or a read signal;
A light detecting means for detecting a light amount emitted from the light source and outputting a light detection signal corresponding to the detected light amount;
A first low-pass filter for smoothing the data write signal and / or read signal;
A second low pass filter for smoothing the photodetection signal;
First difference signal calculation means for calculating a difference signal between the signal smoothed by the first low-pass filter and the signal smoothed by the second low-pass filter;
Variable current means for controlling the current value of the drive current according to the difference signal,
The light detection means is return light detection means for detecting return light reflected by the signal recording medium of light emitted from the light source,
Light output control device you characterized by subtracting the reference value based on the write characteristics of the data to the signal recording medium from said difference signal. 4. The light output control apparatus according to claim 1 , wherein the first and second low-pass filters have the same signal pass band. The first difference signal calculation means, the smoothed signal above the predetermined constant is multiplied the first low-pass filter, according to claim 1, characterized in that calculating the difference signal, 2 or 3. The light output control device according to 3 . 4. The light output control device according to claim 1 , wherein the data writing signal and the light detection signal are signals each having a substantially pulse waveform. It said light detecting means, the light output control device according to claim 1 or 2, wherein it is emitted light detecting means for directly detecting the light emitted from the light source. A light output control device that controls the output of a light source that emits light to a signal recording medium based on a write signal and a predetermined read signal,
A light source that emits light for recording and / or reproducing data on a signal recording medium;
Drive current switching means for switching the drive current to the light source between a first current value and a second current value based on the writing signal;
A light detecting means for detecting a light amount emitted from the light source and outputting a light detection signal corresponding to the detected light amount;
First signal detecting means for detecting a read signal component in the light detection signal and outputting a detection read signal;
Second signal detection means for detecting a write signal component from a difference between the light detection signal and the detection read signal and outputting a detection write signal;
A first low-pass filter for smoothing the detection write signal;
First difference signal calculation means for calculating a difference signal between the signal smoothed by the first low-pass filter and a predetermined reference write signal and outputting a write difference signal;
Second difference signal calculation means for calculating a difference signal between the detection readout signal and a predetermined reference readout signal and outputting the readout difference signal;
First variable current means for controlling a first current value of the drive current in response to the write differential signal;
And a second variable current means for controlling a second current value of the drive current in accordance with the read differential signal. 9. The light output control apparatus according to claim 8, further comprising a second low-pass filter that smoothes the write signal and outputs the predetermined reference write signal. The light output control device according to claim 9, wherein the first and second low-pass filters have the same pass signal band. The first and second low-pass filters can be switched to a plurality of signal pass bands,
It said first and second low-pass filter, claim to be a high signal passband at the start of recording of the data, characterized in that it is switched from the start of recording data to the low signal pass band after a predetermined time elapses 9 The light output control device described. The first and second low-pass filters can be switched to a plurality of signal pass bands,
10. The light output control device according to claim 9 , wherein when accessing the inner and outer circumferences of the disc-shaped signal recording medium, a high signal pass band is used. The light output control device according to claim 9 , wherein the write signal and the detection write signal are signals each having a substantially pulse-shaped waveform. The light according to claim 9, wherein the first difference signal calculation means calculates the difference signal from a signal smoothed by the second low-pass filter multiplied by a predetermined constant. Output control device. 9. The light output control apparatus according to claim 8, wherein the first signal detection means is sample hold means for sampling and holding the read component signal by a sampling signal generated during reproduction. In a recording medium driving apparatus having a light output control unit for controlling the output of a light source that emits light to a signal recording medium,
The light output controller is
A light source that emits light for recording and / or reproducing data on a signal recording medium;
Drive current switching means for switching a current value of a drive current supplied to the light source based on a data write signal and / or a read signal;
A light detecting means for detecting a light amount emitted from the light source and outputting a light detection signal corresponding to the detected light amount;
A first low-pass filter for smoothing the data write signal and / or read signal;
A second low pass filter for smoothing the photodetection signal;
First difference signal calculation means for calculating a difference signal between the signal smoothed by the first low-pass filter and the signal smoothed by the second low-pass filter;
Variable current means for controlling the current value of the drive current according to the difference signal ,
The first and second low-pass filters can be switched to a plurality of signal pass bands,
The first and second low-pass filters have a high signal pass band at the start of data recording and are switched to a low signal pass band after a predetermined time has elapsed from the start of data recording. apparatus. In a recording medium driving apparatus having a light output control unit for controlling the output of a light source that emits light to a signal recording medium,
The light output controller is
A light source that emits light for recording and / or reproducing data on a signal recording medium;
Drive current switching means for switching a current value of a drive current supplied to the light source based on a data write signal and / or a read signal;
A light detecting means for detecting a light amount emitted from the light source and outputting a light detection signal corresponding to the detected light amount;
A first low-pass filter for smoothing the data write signal and / or read signal;
A second low-pass filter for smoothing the photodetection signal;
First difference signal calculation means for calculating a difference signal between the signal smoothed by the first low-pass filter and the signal smoothed by the second low-pass filter;
Variable current means for controlling the current value of the drive current according to the difference signal,
The first and second low-pass filters are switchable to a plurality of signal pass bands,
When accessing the inner and outer peripheries of the disk-shaped signal recording medium, a high signal pass band should be used.
A recording medium driving apparatus characterized by the above. In a recording medium driving apparatus having a light output control unit for controlling the output of a light source that emits light to a signal recording medium,
The light output controller is
A light source that emits light for recording and / or reproducing data on a signal recording medium;
Drive current switching means for switching a current value of a drive current supplied to the light source based on a data write signal and / or a read signal;
A light detecting means for detecting a light amount emitted from the light source and outputting a light detection signal corresponding to the detected light amount;
A first low-pass filter for smoothing the data write signal and / or read signal;
A second low pass filter for smoothing the photodetection signal;
First difference signal calculation means for calculating a difference signal between the signal smoothed by the first low-pass filter and the signal smoothed by the second low-pass filter;
Variable current means for controlling the current value of the drive current according to the difference signal,
The light detection means is return light detection means for detecting return light reflected by the signal recording medium of light emitted from the light source,
Subtracting a reference value based on data writing characteristics with respect to the signal recording medium from the differential signal.
A recording medium driving apparatus characterized by the above. A recording medium driving device having a light output control unit that controls the output of a light source that emits light to a signal recording medium based on a writing signal and a predetermined reading signal,
The light output controller is
A light source that emits light for recording and / or reproducing data on a signal recording medium;
Drive current switching means for switching the drive current to the light source between a first current value and a second current value based on the writing signal;
A light detecting means for detecting a light amount emitted from the light source and outputting a light detection signal corresponding to the detected light amount;
First signal detecting means for detecting a read signal component in the light detection signal and outputting a detection read signal;
Second signal detection means for detecting a write signal component from a difference between the light detection signal and the detection read signal and outputting a detection write signal;
A first low-pass filter for smoothing the detection write signal;
First difference signal calculation means for calculating a difference signal between the signal smoothed by the first low-pass filter and a predetermined reference write signal and outputting a write difference signal;
Second difference signal calculation means for calculating a difference signal between the detection readout signal and a predetermined reference readout signal and outputting the readout difference signal;
First variable current means for controlling a first current value of the drive current in response to the write differential signal;
And a second variable current means for controlling a second current value of the drive current in accordance with the read differential signal.

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