JP2016009511A - Optical disk device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce a time from when the operation of an optical pickup is stopped with high temperature detection to when the operation restarts.SOLUTION: When the temperature of an optical pickup PU measured by a temperature sensor 7 is higher than a first temperature threshold, a main CPU 506 moves the optical pickup PU in a direction approaching a cooling fan to cool it, as a cooling mode at the time of high temperature detection, until its temperature drops to a second temperature threshold, and also causes a semiconductor laser 405 to turn off. When the temperature of the optical pickup PU is lower than the first temperature threshold and the data volume temporarily stored by a buffer memory 503 is greater than a volume threshold, the main CPU 506 moves the optical pickup PU in a direction approaching the cooling fan to cool it while keeping the reproduction operation of an AV decoder unit 504 on, as a cooling mode during reproduction operation, and also causes the semiconductor laser 405 to turn off.

Description

  The present invention relates to an optical disc apparatus that suppresses temperature rise of an optical pickup.

  An optical disk device that operates in a high temperature environment such as a car navigation device has a temperature detection circuit. When a high temperature state is detected, the operation of reading data from the optical disk is stopped to protect the optical pickup. Then, after waiting for natural cooling, the read operation is restarted when the temperature falls below the product guarantee temperature. For this reason, there is a problem that it takes a long time to restart the read operation after detecting the high temperature state and stopping the read operation.

  Therefore, for example, in the optical disc apparatus disclosed in Patent Document 1, the tracking servo mechanism is driven until the temperature of the optical pickup becomes equal to or lower than a predetermined set temperature, and the optical pickup is continuously reciprocated in the radial direction of the optical disc to obtain a heat dissipation effect. Technology has been proposed.

JP 2004-326944 A

  In the optical disc apparatus of Patent Document 1, radiant heat is generated by continuing to drive the tracking servo mechanism while the operation of the optical pickup is stopped, so that it is difficult to shorten the time until the operation of the optical pickup is restarted. There was a problem.

  The present invention has been made to solve the above-described problems, and has an object to increase the cooling effect of the optical pickup and shorten the time from the stop of the operation of the optical pickup due to the high temperature detection to the restart of the operation. .

  An optical disk apparatus according to the present invention includes an optical pickup that reads laser beam data by irradiating a laser beam, a storage unit that temporarily stores data read by the optical pickup, and a decoder that reproduces data temporarily stored in the storage unit Section, a feed section for reciprocating the optical pickup in the radial direction of the optical disk, a temperature sensor for measuring the temperature of the optical pickup, position information of a cooling fan installed to cool the optical disk apparatus, and reading operation of the optical pickup And a second temperature threshold value that is lower than the first temperature threshold value and at which the optical pickup restarts the reading operation, and the temperature of the optical pickup measured by the temperature sensor is the first temperature threshold value. If the temperature threshold is higher than 1, the feed unit is controlled until the temperature falls to the second temperature threshold. Kkuappu to the moving direction toward the cooling fan in which a control unit for cooling.

  According to the present invention, when the temperature of the optical pickup is higher than the first temperature threshold, the optical pickup is moved in the direction approaching the cooling fan and cooled until the temperature falls to the second temperature threshold. The cooling effect of the pickup can be enhanced. Thereby, the time from the stop of the operation of the optical pickup by the detection of the first temperature threshold to the restart of the operation can be shortened.

1 is a block diagram showing a configuration example of an optical disc device according to Embodiment 1 of the present invention. FIG. 3 is a plan view showing a state inside a housing in which the optical disk device according to Embodiment 1 is mounted. 3 is a flowchart showing the operation of the optical disc device according to the first embodiment.

Embodiment 1 FIG.
As shown in FIG. 1, it is a block diagram showing a configuration example of an optical disc apparatus 1 according to the first embodiment. FIG. 2 is a plan view showing the inside of the housing in which the optical disc apparatus 1 according to the first embodiment is accommodated. In FIG. 1 and FIG. 2, only the main part according to the present invention is illustrated, and the other well-known components of the optical disc apparatus 1 are not illustrated.

  As shown in FIG. 2, the optical disk device 1 is housed in a housing 2 of an in-vehicle device such as a car navigation device. The casing 2 is provided with a cooling fan 3 for cooling the inside. In the illustrated example, the cooling fan 3 is installed in the casing 2, but it may be installed in the casing of the optical disc apparatus 1 itself.

  As shown in FIG. 1, the optical disk apparatus 1 mainly includes an optical pickup module unit 4, a signal generation unit 5, a motor driver unit 6, and a temperature sensor 7, and reproduces an optical disk 8. In the first embodiment, the description will focus on the disc playback function of the optical disc apparatus 1, but the optical disc apparatus 1 may also have a recording function.

  The optical pickup module unit 4 includes a spindle motor 401, an optical pickup feed motor 402, a guide shaft 403 (shown in FIG. 2), a feed unit 404, a semiconductor laser (LD; Laser Diode) 405, an actuator 406, An objective lens 407 and a screw shaft 408 are provided. The signal generation unit 5 includes a signal generation matrix amplifier 501, an RF (Radio Frequency) signal processing unit 502, a buffer memory (storage unit) 503, an AV (Audio Visual) decoder unit 504, a servo control unit 505, a main controller A CPU (Central Processing Unit, control unit) 506 and an LD control unit 507 are provided.

  The spindle motor 401 rotates the optical disc 8. The objective lens 407 collects the laser light emitted from the semiconductor laser 405 on the recording surface of the optical disc 8 and reads out the data. The laser beam reflected by the optical disk 8 is detected by a split sensor (not shown) installed inside the actuator 406 and output to the signal generation matrix amplifier 501. The actuator 406 moves the objective lens 407 in the radial direction A of the optical disc 8. These semiconductor laser 405, actuator 406, objective lens 407, split sensor and the like constitute an optical pickup PU.

  The feed unit 404 includes an optical pickup feed motor 402, a guide shaft 403, a screw shaft 408, a gear (not shown), and the like. In a state where the optical pickup PU is supported by the guide shaft 403, the optical pickup feed motor 402 rotates the screw shaft 408 and converts the rotational motion into a linear motion, thereby moving the optical pickup PU in the radial direction A.

  The signal generation matrix amplifier 501 amplifies the signal detected by the split sensor inside the optical pickup PU, and generates a tracking error (TE) signal, an RF signal, and the like. The RF signal processing unit 502 generates video and audio data based on the RF signal output from the signal generation matrix amplifier 501. The buffer memory 503 stores the data generated by the RF signal processing unit 502 for a certain period of time and outputs it to the AV decoder unit 504. The AV decoder unit 504 decodes and outputs the data stored in the buffer memory 503.

  The buffer memory 503 is a shock proof memory for preventing sound skipping due to vibration or the like, for example. The optical pickup module unit 4 reads data from the optical disc 8 at a speed higher than the normal reproduction speed of the AV decoder unit 504 and temporarily stores it in the buffer memory 503 via the signal generation matrix amplifier 501 and the RF signal processing unit 502. The AV decoder unit 504 reads and reproduces data from the buffer memory 503 at a normal reproduction speed. Thereby, the video and audio are reproduced without interruption.

The servo control unit 505 controls the actuator 406 and the optical pickup feed motor 402 so that the laser beam of the optical pickup PU follows the track of the optical disk 8 based on the TE signal output from the signal generation matrix amplifier 501 and the like. By outputting a signal, feedback control of the optical disc apparatus 1 is realized. Since feedback control may be performed using a known technique, detailed description thereof is omitted.
The motor driver unit 6 drives the optical pickup feed motor 402 and the actuator 406 in accordance with the drive signal output from the servo control unit 505.

  As a result, while the optical disk apparatus 1 is reproducing the optical disk 8, the actuator 406 shifts the objective lens 407 in the radial direction A of the optical disk 8 to cause the laser light to follow the track of the optical disk 8, and if the lens shift tolerance is exceeded, When the pickup feed motor 402 is operated, the feed unit 404 feeds the optical pickup PU in the radial direction A of the optical disc 8 and causes the actuator 406 to follow the objective lens 407.

  When an instruction from the main CPU 506 interrupts during the above-described operation, the servo control unit 505 controls the movement of the optical pickup PU according to the instruction. The LD control unit 507 switches on / off the semiconductor laser 405 of the optical pickup PU in accordance with an instruction from the main CPU 506.

The temperature sensor 7 measures the temperature of the optical pickup PU and outputs it to the main CPU 506. The temperature sensor 7 may be installed anywhere as long as the temperature of the optical pickup PU can be measured. For example, the temperature sensor 7 is installed inside the optical pickup PU, on a substrate on the movement path of the optical pickup PU, or the like.
Among the components constituting the optical pickup PU, the semiconductor laser 405 is likely to reach a high temperature and has no proof strength in a high temperature environment. Therefore, the temperature sensor 7 is installed inside the optical pickup PU to control the temperature of the semiconductor laser 405. It is preferable to measure directly.
On the other hand, when the temperature sensor 7 is installed on the optical pickup moving path of the substrate, the optical pickup is preliminarily determined from the substrate temperature in order to fill a gap between the actual temperature of the optical pickup PU and the temperature of the substrate measured by the temperature sensor 7. It is preferable to derive a temperature correction formula for calculating the temperature of the PU, and calculate the temperature of the optical pickup PU from the temperature of the substrate measured by the temperature sensor 7.

  The main CPU 506 constantly monitors the temperature of the optical pickup PU output from the temperature sensor 7 and the video and audio data capacities stored in the buffer memory 503. Based on the monitoring result, the main CPU 506 instructs the servo control unit 505 to control the movement of the optical pickup PU, and also instructs the LD control unit 507 to control the operation of the semiconductor laser 405. The main CPU 506 controls the operation of the AV decoder unit 504 based on the monitoring result. The main CPU 506 controls the entire operation of the optical disc apparatus 1 and controls the operation of the spindle motor 401 and the like in addition to the above.

Next, the operation of the main CPU 506 will be described with reference to the flowchart of FIG.
The main CPU 506 sets the high temperature detection temperature (first temperature threshold) to K [° C.] and sets the high temperature detection release temperature (second temperature threshold) to L [° C.] after the optical disk device 1 is powered on. (Step ST1), the seek address near the cooling fan 3 is set to M (Step ST2), and the necessary minimum capacity (capacity threshold) of the data in the buffer memory 503 is set to R (Step ST3).

K, L, M, and R are values given to the main CPU 506 in advance.
The high temperature detection temperature K is, for example, the upper limit value (for example, 85 ° C.) of the operation guarantee temperature at which the optical pickup PU operates stably. The high temperature detection release temperature L is set to a value lower than the high temperature detection temperature K (for example, 60 ° C.).
The required minimum capacity R of data in the buffer memory 503 is a data capacity required for the AV decoder unit 504 to continue reproducing video and audio data when data reading from the optical disk 8 by the optical pickup PU is interrupted.

FIG. 2 schematically shows the arrangement of the optical pickup PU, the guide shaft 403 and the screw shaft 408 among the components accommodated in the optical disc apparatus 1. The optical pickup PU is guided by the guide shaft 403 and reciprocates in the radial direction A.
For example, when the cooling fan 3 is installed at the B1 position of the housing 2, the optical pickup PU is closest to the cooling fan 3 at the B1 position when the optical pickup PU moves to the B2 position. . Alternatively, when the cooling fan 3 is installed at the C1 position of the housing 2, the optical pickup PU is closest to the cooling fan 3 at the C1 position when the optical pickup PU is moved to the C2 position. To do.
In the example of FIG. 2, the position where the optical pickup PU is closest to the cooling fan 3 is the seek address M in order to enhance the cooling effect of the optical pickup PU. However, the position is not limited to this position, and the cooling fan is not limited to this position. It is sufficient if the airflow near 3 is large.

  In step ST4, the main CPU 506 instructs each unit of the optical disc apparatus 1 to start the reproduction operation of the optical disc 8. Further, the main CPU 506 starts monitoring the temperature P [° C.] of the optical pickup PU measured by the temperature sensor 7 and the data capacity Q of the buffer memory 503 (step ST5). When the temperature P of the optical pickup PU is lower than the high temperature detection temperature K (step STST6 “YES”), the main CPU 506 performs the cooling mode (steps ST8 to ST13) during the reproduction operation, and the temperature P of the optical pickup PU is high. When the temperature is equal to or higher than the detected temperature K (step ST6 “NO”), the cooling mode (steps ST14 to ST20) at the time of detecting the high temperature is performed.

  In the cooling mode during playback operation (step ST6 “YES”), the main CPU 506 needs the data capacity Q of the audio and video data stored in the buffer memory 503 so that the AV decoder unit 504 can continue playback. A comparison is made as to whether it is larger than the required minimum capacity R of the audio and video data (step ST7). When the data capacity Q stored in the buffer memory 503 is larger than the necessary minimum capacity R (“YES” in step ST7), the main CPU 506 once holds the seek address S of the current reproduction position of the optical pickup PU ( In step ST8, the servo controller 505 is instructed to move the optical pickup PU to the seek address M near the cooling fan 3 (step ST9). Subsequently, the main CPU 506 instructs the LD control unit 507 to turn off the semiconductor laser 405 of the optical pickup PU to stop the reading operation (step ST10), and waits until a predetermined time T1 elapses (step ST11). . After the elapse of the predetermined time T1, the main CPU 506 instructs the LD control unit 507 to turn on the semiconductor laser 405 of the optical pickup PU to restart the reading operation (step ST12), and instructs the servo control unit 505 to perform the light. The pickup PU is moved to the seek address S held at step ST8 (step S13).

  On the other hand, when the data capacity Q stored in the buffer memory 503 is equal to or smaller than the necessary minimum capacity R (step ST7 “NO”), the main CPU 506 continues the reproducing operation of the optical disc apparatus 1.

  By moving the optical pickup PU to the seek address M where the airflow of the cooling fan 3 is large in the cooling mode during the reproduction operation, the cooling effect of the optical pickup PU can be enhanced. During this time, since the optical pickup feed motor 402 is stopped, generation of radiant heat can be suppressed. Moreover, the temperature rise of the optical pickup PU can be suppressed by turning off the semiconductor laser 405. Thereby, the temperature rise of the optical pickup PU under a high temperature environment is suppressed, and it becomes easy to avoid the operation stop due to the cooling mode at the time of high temperature detection described later, and the proof stress under the high temperature environment is improved.

  Incidentally, the fixed time T1 in step ST11 is, for example, the time during which the reproduction of the audio and video data with the minimum required capacity R can be continued, and the optical pickup PU from the seek address S at the current position to the seek address M near the cooling fan 3. The time required for saving and the time required for returning from the seek address M to the original seek address S are set as the combined time. Therefore, the AV decoder unit 504 can continue to reproduce the audio and video data for a certain time T1 during which the optical pickup PU is retracted in the vicinity of the cooling fan 3 and data reading from the optical disk 8 is stopped.

The fixed time T1 may be a variable value instead of a fixed value. For example, the main CPU 506 estimates the time during which the reproduction of the audio and video data can be continued based on the data capacity Q stored in the buffer memory 503, and the estimated time and the time required for saving and restoring the optical pickup PU described above. And the fixed time T1 may be calculated.
In this case, the longer the data capacity Q of the buffer memory 503, the longer the cooling time of the optical pickup PU can be secured, and the cooling effect during the reproduction operation can be enhanced.

  In the cooling mode at the time of high temperature detection (step ST6 “NO”), the main CPU 506 once holds the seek address S of the current reproduction position of the optical pickup PU (step ST14), and then instructs the servo controller 505. The optical pickup PU is moved to the seek address M near the cooling fan 3 (step ST15). Subsequently, the main CPU 506 instructs the LD control unit 507 to turn off the semiconductor laser 405 of the optical pickup PU and stop the data reading operation, and also stop the audio and video data reproducing operation of the AV decoder unit 504 (step ST16). ). At this time, the main CPU 506 may instruct the servo control unit 505 to stop the rotation drive of the optical disc 8 by the spindle motor 401.

  After that, the main CPU 506 compares the temperature P of the optical pickup PU with the high temperature detection release temperature L every time the fixed time T2 has elapsed (step ST17) (step ST18). When the temperature P of the optical pickup PU is lower than the high temperature detection release temperature L (step ST18 “YES”), the main CPU 506 instructs the LD control unit 507 to turn on the semiconductor laser 405 of the optical pickup PU and restart the reading operation. At the same time, the reproduction operation of the audio and video data of the AV decoder unit 504 is resumed (step ST19). Subsequently, the main CPU 506 instructs the servo control unit 505 to move the optical pickup PU to the seek address S held in step ST14 (step ST20).

  Also in the cooling mode at the time of high temperature detection, the optical pickup PU is moved to the seek address M where the airflow of the cooling fan 3 is large, the optical pickup feed motor 402 is stopped, and the semiconductor laser 405 is turned off as in the cooling mode at the time of the reproduction operation. Therefore, the temperature rise of the optical pickup PU can be suppressed and the cooling effect can be enhanced. As a result, the time from when the high temperature is detected and the operation of the optical pickup PU is stopped to when it resumes can be shortened, and the proof stress in a high temperature environment is improved.

  As described above, according to the first embodiment, the optical disc apparatus 1 includes the optical pickup PU that irradiates laser light and reads data from the optical disc 8, the buffer memory 503 that temporarily stores the data read by the optical pickup PU, and the buffer AV decoder unit 504 that reproduces data temporarily stored in memory 503, feed unit 404 that reciprocates optical pickup PU in the radial direction of optical disc 8, temperature sensor 7 that measures the temperature of optical pickup PU, and optical disc Position information (seek address M) of the cooling fan 3 installed to cool the device 1, a first temperature threshold (high temperature detection temperature K) for stopping the data reading operation of the optical pickup PU, and the first temperature A second temperature at which the optical pickup PU resumes the reading operation at a temperature lower than the threshold value. When the temperature of the optical pickup PU measured by the temperature sensor 7 is higher than the first temperature threshold, the feed unit 404 is controlled until the temperature falls to the second temperature threshold. Then, the optical pickup PU is moved in a direction approaching the cooling fan 3 and is configured to include a main CPU 506 for cooling. For this reason, the cooling effect of the optical pickup PU can be enhanced, and the time from the stop of the operation of the optical pickup PU to the restart of the operation due to the high temperature detection can be shortened.

  Further, according to the first embodiment, the main CPU 506 has a capacity threshold (required minimum capacity R) of data temporarily stored in the buffer memory 503, and the temperature of the optical pickup PU measured by the temperature sensor 7 is the first. When the temperature is lower than 1 temperature threshold (high temperature detection temperature K) and the capacity of data temporarily stored in the buffer memory 503 is larger than the capacity threshold, the optical pickup PU is cooled while the reproduction operation of the AV decoder unit 504 is continued. It moved to the direction which approaches the fan 3, and it was made to cool. For this reason, the optical pickup PU can be efficiently cooled during the reproducing operation, and the temperature rise can be suppressed.

  Further, according to the first embodiment, the main CPU 506 turns off the semiconductor laser 405 when the optical pickup PU is moved in a direction approaching the cooling fan 3. For this reason, the temperature rise of the optical pickup PU can be suppressed during the reproduction operation of the AV decoder unit 504 and when the operation of the optical pickup PU is stopped due to high temperature detection, and the cooling effect can be further enhanced.

  Further, according to the first embodiment, the main CPU 506 calculates the time (a certain time T1) during which the AV decoder unit 504 can continue the reproduction operation based on the capacity of data temporarily stored in the buffer memory 503, Before the time elapses, the optical pickup PU is returned to the original position from the cooling fan 3 side. For this reason, the cooling time of the optical pickup PU can be lengthened, and the cooling effect can be further enhanced.

  In the present invention, any component of the embodiment can be modified or any component of the embodiment can be omitted within the scope of the invention.

  DESCRIPTION OF SYMBOLS 1 Optical disk apparatus, 2 Housing | casing, 3 Cooling fan, 4 Optical pick-up module part, 5 Signal generation part, 6 Motor driver part, 7 Temperature sensor, 8 Optical disk, 401 Spindle motor, 402 Optical pick-up feed motor, 403 Guide shaft, 404 Feed unit, 405 Semiconductor laser, 406 Actuator, 407 Objective lens, 408 Screw shaft, 501 Signal generation matrix amplifier, 502 RF signal processing unit, 503 Buffer memory (storage unit), 504 AV decoder unit, 505 Servo control unit, 506 main CPU (control unit), 507 LD control unit, PU optical pickup.

Claims (4)

An optical pickup that reads the data of the optical disk by irradiating the laser beam;
A storage unit for temporarily storing data read by the optical pickup;
A decoder unit for reproducing data temporarily stored in the storage unit;
A feed unit for reciprocating the optical pickup in the radial direction of the optical disc;
An optical disk device comprising a temperature sensor for measuring the temperature of the optical pickup,
Position information of a cooling fan installed to cool the optical disk device, a first temperature threshold value for stopping the reading operation of the optical pickup, and a temperature lower than the first temperature threshold value and the optical pickup reads When the temperature of the optical pickup measured by the temperature sensor is higher than the first temperature threshold, the feed unit has a second temperature threshold for restarting the operation until the temperature falls to the second temperature threshold. An optical disc apparatus comprising: a control unit that controls the optical pickup so as to move the optical pickup in a direction approaching the cooling fan.   The control unit has a capacity threshold of data temporarily stored in the storage unit, the temperature of the optical pickup measured by the temperature sensor is lower than the first temperature threshold, and is temporarily stored in the storage unit. 2. The apparatus according to claim 1, wherein when the capacity of stored data is greater than the capacity threshold, the optical pickup is moved in a direction approaching the cooling fan while the reproduction operation of the decoder unit is continued to cool. Optical disk device.   3. The optical disc apparatus according to claim 1, wherein the control unit turns off the laser light when the optical pickup is moved in a direction approaching the cooling fan.   The control unit calculates a time during which the decoder unit can continue the reproduction operation based on a capacity of data temporarily stored in the storage unit, and the optical pickup is connected to the cooling fan before the time elapses. 3. The optical disk apparatus according to claim 2, wherein the optical disk apparatus is returned to the original position.

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