JP2005004896A - Optical disk reproducing apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical disk reproducing apparatus having a function capable of suppressing consumed power in reproduction operation to the utmost and of power saving. <P>SOLUTION: There is provided a system controller 11 which controls the operation such that after a spindle motor drive circuit 51 is actuated and the number of revolution of a spindle motor 2 reaches a predetermined one, a spindle motor servo-circuit 511 is interrupted in its operation after the lapse of predetermined time, and then a data signal from a mini-disk 1 is continuously read by an optical pickup 3 and is continuously demodulated through a signal processing circuit 71. Hereby, the data signal from the optical disk can be continuously demodulated also while the spindle motor servo-circuit 511 is interrupted in its operation and the mini-disk 1 is rotated with inertia. The consumed power is therefore reduced to ensure the power saving while the mini-disk 1 is rotated by the inertia. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical disc reproducing apparatus for reproducing information signals such as audio / music data recorded on an optical disc.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, as an optical disk reproducing apparatus, an MD reproducing apparatus that reproduces, for example, a mini disk (MD) as an optical disk that is a recording medium is known. This MD playback device is a digital audio device that plays back information signals such as voice / music data digitally recorded on a mini-disc. The information signal digitally recorded on the mini-disc is subjected to time-axis compression. Therefore, the MD playback device performs digital / analog conversion after extending the time-axis of the information signal read from the mini-disc. Play the original voice / music data.
[0003]
In the case of this MD playback apparatus, when the rotation of the mini disc is 1 × speed, for example, the voice / music data as the main information is read from the mini disc at a processing speed of 1.4 Mbit / sec. Data decompression is performed at a processing speed of 0.3 Mbit / sec. Therefore, in this MD reproducing apparatus, in order to absorb the difference between the data reading speed of the optical pickup and the sending speed of the data to be reproduced with time expansion, the time-compressed voice / music data read from the mini-disc is stored. Once stored in a semiconductor memory such as a D-RAM, data is read from the semiconductor memory at a processing speed of, for example, 0.3 Mbit / second and reproduced.
[0004]
Also, in this MD playback device, the time-compressed audio / music data read from the mini-disc is obtained by utilizing the difference between the data reading speed of the optical pickup and the sending speed of the data to be played back with time expansion. More than a predetermined amount of data is always stored in the semiconductor memory.
[0005]
By storing more than a predetermined amount of data in this way, even if a disturbance such as vibration is applied to the main body of the MD reproducing apparatus and the optical pickup is removed from the correct track, the data in the semiconductor memory is not lost. In addition, if the optical pickup is returned to the correct track position, the reproduced sound can be prevented from being interrupted. Such a semiconductor memory is called a so-called shock proof memory, and in the case of a portable MD reproducing apparatus, for example, a 16 Mbit D-RAM is generally used.
[0006]
Such a shock proof memory works as a work RAM in which a part of its capacity (storage area) absorbs the difference in data transfer speed of the data input / output of the memory during reproduction. Information such as U-TOC (User Table Of Contents) information of a mini-disc that is partially reproduced is stored, and the remaining capacity is used for shock proofing.
[0007]
In other words, when the shock proof memory is a 16-Mbit D-RAM and the rotation of the mini disk is 1.5 times speed, the difference in processing speed between reading data from the mini disk and time axis expansion is as follows: 1.5 × 1.4−0.3 = 1.8 bits / second, the memory is full in about 9 seconds after the start of reading data from the minidisk, and the playback time is about 48 seconds. Are stored.
[0008]
When the data stored in the shock proof memory is full, the data read from the mini-disc is not stored in the shock proof memory for a predetermined time. Only the data is read out. As a result, an empty area is generated in the capacity of the shock proof memory, and the data read from the mini-disc is sequentially stored in this empty area again, and when the data becomes full, the shock Only reading of data from the proof memory is performed. Thereafter, the same operation is repeated.
[0009]
On the other hand, in a portable MD playback device that is easy to carry, a rechargeable battery or a dry battery is used as a power source of the MD playback device. In this case, since the time that can be used continuously is limited without replacing the battery, it is desirable to have a configuration that can be used for a long time while reducing power consumption as much as possible. After the storage capacity is full, read data from the mini-disc or stop the operation of the optical pickup or spindle motor, etc., and only extend the time axis until the stored data in the memory reaches the specified amount. An operation is performed to reduce power consumption due to idle reading of data from the minidisk.
[0010]
Furthermore, in order to reduce power consumption, an optical disk for reading data by rotating a spindle motor for rotating an optical disk at a speed faster than the normal linear speed as in the prior art disclosed in Patent Document 1. In a pause mode in which reading of data from an optical disk is paused as in the prior art disclosed in Patent Document 2, the power consumption is reduced by shortening the irradiation time of the laser beam to the spindle motor. Is set to be lower than the rotation speed in the playback mode, and the optical disk is kept rotating, and the power consumption is excessively reduced by starting the spindle motor from the complete stop. Things are known.
[0011]
[Patent Document 1]
JP-A-11-149716
[Patent Document 2]
JP 2000-348431 A
[0012]
[Problems to be solved by the invention]
However, in the prior art as described above, in order to rotate the optical disk at a constant linear velocity or a constant angular velocity during the data reading period, a spindle motor drive circuit, a rotation speed detection means for detecting the rotation speed of the spindle motor, and The spindle motor servo circuit is operated, and it is necessary to continue the operation until the amount of data stored in the memory reaches a predetermined amount. During this time, there is a problem that power for driving the spindle motor is consumed. Become.
[0013]
The present invention has been made to solve the above-described problems, and an object of the present invention is to provide an optical disc reproducing apparatus having a function of suppressing power consumption as much as possible during reproducing operation and saving power.
[0014]
[Means for Solving the Problems]
In order to achieve the above object, according to the present invention, in an optical disk reproducing apparatus for reproducing information recorded on an optical disk, the rotational speed of a spindle motor that rotates the optical disk reaches a predetermined rotational speed, and after a predetermined time has elapsed, There is provided an optical disk reproducing apparatus comprising a system controller for controlling so that information recorded on the optical disk can be demodulated after the operation of the servo means of the spindle motor is stopped.
[0015]
In this configuration, when reproducing the information recorded on the optical disk, when the rotation speed of the spindle motor that rotates the optical disk reaches a predetermined rotation speed, the servo means of the spindle motor is stopped. Rotation by inertia makes it possible to demodulate information recorded on the optical disk. Therefore, according to the optical disk reproducing apparatus having this configuration, when the rotational speed of the spindle motor that rotates the optical disk reaches a predetermined rotational speed, the servo means of the spindle motor is stopped, so that the optical disk is rotated by inertia. During this time, power consumption is reduced and power saving can be achieved.
[0016]
The present invention also provides an optical pickup that optically reads information recorded on an optical disc and converts it into an electrical signal, an RF amplifier that generates a data signal and a servo signal based on an output signal of the optical pickup, and the optical disc. A spindle motor that rotates, servo control signal generation means that generates servo control signals for controlling the spindle motor and the optical pickup based on the servo signal, and servos the optical pickup based on the servo control signal Optical pickup servo means for controlling, spindle motor servo means for servo-controlling a spindle motor based on the servo control signal, and demodulation for demodulating recording information on the optical disk based on an RF signal which is a data signal from the RF amplifier Means and the demodulated memory Memory for storing information, decompression processing means for performing processing including decompression / error correction by reading out a data signal of recording information from the memory, spindle motor driving means for driving and controlling the spindle motor, and rotation of the spindle motor Rotation speed detecting means for detecting the number, and a PLL for enabling reading of the data signal from the RF amplifier by generating a reproduction clock based on the data signal from the RF amplifier and controlling the reproduction clock ( In an optical disk reproducing apparatus including a Phase Locked Loop circuit, after the spindle motor driving means is activated and the rotation speed detecting means detects that the rotation speed of the spindle motor has reached a predetermined rotation speed. The spindle motor servo means stops operating after a predetermined time has elapsed. And an optical disk comprising a system controller for performing control so as to continue reading data signals from the optical disk by the optical pickup and continue to demodulate by the demodulating means while being followed by the PLL circuit. A playback device is provided.
[0017]
In this configuration, only the time during which the data signal is read from the rotating optical disk, that is, the time shorter than the servo ON time of the spindle motor servo means, for example, 3 seconds out of 9 seconds which is the conventional servo ON time. The optical disk is rotated at a constant rate for only one second, and thereafter, the spindle motor servo means is turned OFF, the optical disk is rotated by inertia, and the rotation speed is detected by the rotation speed detection means, and the data signal from the RF amplifier is used. A reproduction clock is generated, this reproduction clock is controlled, and the data signal read from the optical disk is continuously demodulated by the demodulating means while the data signal from the RF amplifier is made to follow by the PLL circuit. You can continue.
[0018]
Therefore, according to the optical disk reproducing apparatus having this configuration, when the rotational speed of the spindle motor that rotates the optical disk reaches a predetermined rotational speed, the spindle motor servo means is stopped and the optical disk is rotated by inertia. The data signal from the optical disc can be continuously demodulated, and while the optical disc is rotated by inertia, the power consumption is reduced and the power can be saved.
[0019]
Further, the present invention provides a spindle motor servo means that is operated after a predetermined time has elapsed after the spindle motor driving means is actuated to detect that the rotational speed of the spindle motor has reached a predetermined rotational speed. After the operation is stopped, the data signal from the optical disk is continuously read by the optical pickup, demodulated by the demodulating means while being followed by the PLL circuit, and the demodulated data signal is stored in the memory. System controller that performs control to stop the supply of power to the PLL circuit and an optical pickup servo means, optical pickup servo means, other servo related means, and a PLL circuit ing.
[0020]
According to this configuration, the data signal read from the optical disk is stored in the memory, and when the storage amount reaches a predetermined amount, the data stored in the memory is stored in the same manner as in the normal intermittent servo operation. Stops the operation of components (optical pickup, RF amplifier, servo control signal generation means, optical pickup servo means, other servo-related means, PLL circuit) other than circuits that read out and expand into audio / music signals Thus, power consumption can be reduced.
[0021]
Further, the present invention provides a spindle motor servo means that is operated after a predetermined time has elapsed after the spindle motor driving means is actuated to detect that the rotational speed of the spindle motor has reached a predetermined rotational speed. After the operation is stopped, when the data signal from the optical disk is continuously read by the optical pickup and then demodulated by the demodulating means while being followed by the PLL circuit, the demodulated data signal is stored in the memory, and the storage amount When the rotational speed of the optical disk has decreased to a preset rotational speed before reaching the predetermined amount, the spindle motor servo means is operated again until the storage amount in the memory reaches the predetermined amount. Is provided with a system controller that performs control so as to store a predetermined amount of data.
[0022]
According to this configuration, the rotational speed of the optical disk before the storage amount of the data stored in the memory reaches a predetermined amount due to some reason such as the attitude of the portable device when the optical disk playback device is used for portable use. Therefore, it is possible to prevent data unreadable operation due to exceeding the logic range of the PLL circuit, and to store data in the memory with certainty.
[0023]
Further, the present invention provides a spindle motor servo means that is operated after a predetermined time has elapsed after the spindle motor driving means is actuated to detect that the rotational speed of the spindle motor has reached a predetermined rotational speed. When the operation is stopped and the data signal from the optical disk is continuously read by the optical pickup and demodulated by the demodulating means while being followed by the PLL circuit, and the demodulated data is to be stored in the memory, the demodulated data When it is determined that there are many errors in the signal, a system controller is provided for controlling the spindle motor servo means to operate again even if the rotational speed of the optical disc does not decrease to a preset rotational speed.
[0024]
According to this configuration, when it is determined that there are many errors in the demodulated data signal, in order to read the data signal more reliably, the reading by the normal inertia of the optical disk is not continued, but the spindle motor servo means Can be dealt with so that the amount of data stored in the memory is not insufficient by performing reading in a state where the spindle motor servo is applied.
[0025]
Further, the present invention is demodulated before a predetermined time elapses after the spindle motor driving means is actuated and the rotation speed detecting means detects that the spindle motor has reached the predetermined rotation speed. When it is determined that there are many errors in the data signal, there is provided a system controller that performs control so that the spindle motor servo means does not stop operating but remains driven.
[0026]
According to this configuration, it is determined that there are many errors in the demodulated data signal before the predetermined time elapses after the rotation speed detection means detects that the rotation speed of the spindle motor has reached the predetermined rotation speed. In this case, it is possible to cope with the amount of data stored in the memory not to be insufficient by reading the data signal reliably while the spindle motor servo means is driven without being turned off.
[0027]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. FIG. 1 is a block diagram showing the configuration of an MD playback apparatus according to an embodiment of the present invention. In FIG. 1, this MD reproducing apparatus includes a spindle motor 2 that rotates a mini-disc 1 as an optical disc, an optical pickup 3 that optically reads information on the mini-disc 1 and converts it into an electrical signal and outputs an RF signal, A thread motor 4 that drives the optical pickup 3 stepwise in the radial direction of the mini disk 1, and a driver circuit 5 that drives the spindle motor 2, the optical pickup 3, and the thread motor 4 are provided.
[0028]
The optical pickup 3 includes a light emitting element that intermittently emits a laser beam, and an optical system that includes a collimator lens, a beam splitter, and an objective lens for guiding the emitted light from the light emitting element to the recording surface of the mini-disc 1. In addition, each actuator for controlling the position of the objective lens to perform tracking and focusing of the laser beam with respect to the read track of the mini-disc 1 and a photodetector for detecting the return light from the mini-disc 1 and converting it into an electrical signal (both shown in FIG. (Not shown).
[0029]
The driver circuit 5 includes a spindle motor drive circuit 51 that drives the spindle motor 2 and an optical pickup drive circuit 52 that drives the thread motor 4 and the actuator to control the optical pickup 3. The spindle motor drive circuit 51 includes a spindle motor servo circuit 511 that servo-controls the spindle motor 4 and a rotation speed detection circuit 512 that detects the rotation speed of the spindle motor 2 (mini disk 1). The optical pickup drive circuit 52 includes an optical pickup servo circuit 521 that servo-drives the sled motor 4 and the actuator to servo-control the optical pickup 3.
[0030]
The MD reproducing apparatus also includes an RF amplifier 6 that amplifies the RF signal from the optical pickup 3 and a decoder LSI (large scale integrated circuit) 7 that receives the RF signal from the RF amplifier 6 and performs predetermined signal processing. A shock proof memory 8 that temporarily stores information processed by the decoder LSI 7; an amplifier circuit 9 that amplifies an audio signal output from the decoder LSI 7 and supplies the amplified audio signal to the headphones 10; and controls the entire apparatus. A system controller 11, a power supply circuit 12 that supplies power to each part of the apparatus, a power supply voltage detection circuit 13 that detects a power supply voltage, and a power supply 14 of the apparatus. The headphone 10 may be a speaker.
[0031]
The decoder LSI 7 includes a signal processing circuit 71 serving as a demodulating unit that performs processing such as extraction of an address signal, demodulation of a main data signal, and error correction based on the RF signal amplified by the RF amplifier 6. A servo control signal generation circuit 72 that generates a servo control signal to be supplied to the spindle motor servo circuit 511 and the optical pickup servo circuit 521 based on the servo signal obtained from the RF amplifier 6, and a data signal from the RF amplifier 6 A PLL circuit 73 for making it possible to read the data signal from the RF amplifier 6 by generating a reproduction clock and controlling the reproduction clock, and compressing the input information signal by extending the time axis according to a predetermined format Memory decompression circuit 74 and memory control for controlling shock proof memory 8 A road 75, and the information signal outputted from the audio expansion circuit 74 and a D / A converter 76 for converting D / A.
[0032]
The mini-disc 1 has concentric or spiral tracks, and information signals such as voice / music data are digitally recorded along the tracks. In addition to the main information such as voice / music data, the mini-disc 1 also includes U-TOC information including a disc title name, each track title name, and address information of a memory storing the voice / music data. It is recorded.
[0033]
When reproducing the information signal recorded on the mini-disc 1, the MD reproducing apparatus rotates the mini-disc 1 with a spindle motor 2 at a constant linear velocity or a constant angular velocity, and the optical pickup 3 with a sled motor 4. Step drive is performed in the radial direction of the disk 1. The information signal is read by irradiating a laser beam from the optical pickup 3 positioned on a predetermined track toward the track, and detecting the intensity change of the reflected light again by the optical pickup 3.
[0034]
The drive control of the optical pickup 3, the sled motor 4, and the spindle motor 2 is all performed by the driver circuit 5. As described above, the driver circuit 5 includes the spindle motor drive circuit 51 and the optical pickup drive circuit 52.
[0035]
The optical pickup 3 sends an information signal (compressed data) read from the mini disk 1 to the RF amplifier 6. The RF amplifier 6 amplifies the information signal and outputs the amplified information signal to the decoder LSI 7 and generates a servo control signal such as a tracking error signal and a focus error signal based on the servo signal included in the information signal. 72 and sent to the servo circuit 77 in the decoder LSI 7.
[0036]
The servo circuit 77 in the decoder LSI 7 controls the driver circuit 5 in accordance with the servo control signal, the address signal from the signal processing circuit 71 in the decoder LSI 7 and the control signal from the system controller 11 realized by a microcomputer or the like. Thus, servo control of various operations such as tracking, focusing, and disk spinning is performed.
[0037]
The signal processing circuit 71 in the decoder LSI 7 performs processing such as address signal extraction, main signal demodulation, and error correction on the RF signal (information signal) amplified by the RF amplifier 6, and these processing is completed. The information signal is sent to the memory control circuit 75 in the decoder LSI 7. The memory control circuit 75 is a means for controlling the writing and reading of information with respect to the shock proof memory 8, and the information signal from the signal processing circuit 71 is once written into the shock proof memory 8. The writing rate at this time is, for example, 1.5 × 1.4 Mbit / sec when the rotation of the mini disk 1 is 1.5 times speed. The memory control circuit 75 reads out the information signal from the shock proof memory 8 at a read rate of 0.3 Mbit / sec, for example, and sends it to the audio decompression circuit 74 in the decoder LSI 7.
[0038]
Thus, between the speed at which the information signal read from the mini-disc 1 is written into the shock proof memory 8 and the speed at which the information signal is sent from the shock proof memory 8 to the audio decompression circuit 74, In the case of the example, there is a difference of 1.5 × 1.4−0.3 = 1.8 Mbit / sec. Due to the difference in processing speed, the information signal before the time-axis compression is released is stored in the shock proof memory 8.
[0039]
Further, the shock proof memory 8 also stores U-TOC information (disc title name, each track title name, etc.) read from the mini disc 1, and the U-TOC information can be used to store, for example, a mini The start position, end position, or time information of each music piece recorded on the disc 1 can be obtained.
[0040]
Subsequently, the audio decompression circuit 74 in the decoder LSI 7 decompresses the input information signal by expanding the time axis in accordance with a predetermined format, and the decompressed information signal is converted into a D / A in the decoder LSI 7. Send to converter 76. The D / A converter 76 generates voice / music data (analog signal) by performing digital / analog conversion on the information signal (digital signal) that has been decompressed. Then, by supplying the analog voice / music data to the amplifier circuit 9, the volume of the voice / music data is adjusted, and the voice / music data is reproduced and output to the user through the headphones 10.
[0041]
Further, the system controller 11 constantly checks the voltage value of the power supply 14 detected by the power supply voltage detection circuit 13 and confirms whether or not the voltage value of the power supply 14 is suitable for the reproducing operation of the mini disc 1. Therefore, power is supplied to the power supply circuit 12. The power supply circuit 12 is composed of a DC-DC conversion circuit or the like, and supplies necessary voltages to each part of the MD reproducing apparatus. As the power source 14, a portable lithium ion rechargeable battery or a Ni-MH rechargeable battery may be used.
[0042]
FIG. 2 is a flowchart for explaining the operation of the MD playback apparatus of the present embodiment. The operation of the MD playback device will be described below with reference to this flowchart.
[0043]
The MD playback device detects the memory storage amount stored in the shock proof memory 8 in step S1 while the mini disc 1 is being played back. Here, when it is confirmed that the memory storage amount is not less than the minimum set value Rmin that needs to newly add data to the shock proof memory 8, the process returns to the process of step S1 again, and the memory The mini-disc 1 continues to be played until the storage amount becomes smaller than the minimum set value Rmin.
[0044]
If it is confirmed in step S1 that the memory storage amount is smaller than the minimum set value Rmin, the process proceeds to step S2. In step S 2, the spindle motor 2 is started up under the control of the servo circuit 77 and the driver circuit 5 in the decoder LSI 7 in order to start reading data that has been compressed and written on the minidisk 1. Thereafter, in step S3, the rotation number detection from the driver circuit 5 to the decoder LSI 7 is performed to determine whether or not the rotation of the activated spindle motor 2 has reached the number of rotations until the rotation of the mini disk 1 is pulled into the servo. Check with signal FG.
[0045]
If it is determined in step S3 that the rotational speed of the mini disk 1 has not reached the rotational speed until it can be pulled into the servo, it waits until it reaches the predetermined rotational speed, and has reached the predetermined rotational speed. If confirmed, the process proceeds to step S4. In step S4, the laser of the optical pickup 3 is turned on, and in step S5, all servos are activated to prepare for data reading at a constant linear velocity or constant angular velocity.
[0046]
Thereafter, in step S6, reading of data written on the mini-disc 1 is started. Next, in step S7, it is confirmed whether or not there are many errors in the read data, based on the state of the mini disc 1 and the conditions for recording information on the mini disc 1. If the error value of the read data is equal to or greater than e, the process returns to step S6 in order to read the data in the servo ON state without entering the intermittent servo.
[0047]
If it is determined in step S7 that the error value is less than e, the state of reading data from the minidisc 1 is good, and the process proceeds to step S8. In step S8, it is confirmed whether or not the elapsed time after servo activation, that is, the time from the start of reading data is t1 or more. If t1 has not yet been reached, the process returns to step S6.
[0048]
On the other hand, if it is detected in step S8 that the time from the start of reading data is t1 or more, the process proceeds to step S9. In step S9, only the spindle servo (spindle motor servo circuit 511) is turned OFF, and the other servos are kept ON, and data is continuously read from the mini disk 1 rotating by inertia in step S10.
[0049]
In step S11, it is confirmed whether or not there are many errors in the data read in step S10. If the error value is equal to or greater than e, the process returns to step S5 again to reliably read the data and the spindle servo. (Spindle motor servo circuit 511) is activated and data reading is continued.
[0050]
If it is determined in step S11 that the error value is less than e, the process proceeds to step S12, where it is confirmed that the rotation speeds of the mini disk 1 and the spindle motor 2 rotating by inertia are equal to or greater than the specified value fL. To do. If the rotation speed of the spindle motor 2 is less than the specified value fL, the process returns to step S5 and restarts the spindle servo (spindle motor servo circuit 511) so that the rotation speed does not decrease and the data cannot be read. To ensure that the data can be read.
[0051]
If it is determined in step S12 that the rotational speeds of the mini disk 1 and the spindle motor 2 are the prescribed value fL, and it is detected that the PLL circuit 73 in the decoder LSI 7 for reading data from the mini disk 1 can sufficiently follow, In step S13, the memory storage amount stored in the shock proof memory 8 is detected. If it is determined that the memory storage amount has not yet reached the maximum set value Rmax that data need not be added to the shock proof memory 8, the process returns to step S10, and the mini disk Continue reading data from 1.
[0052]
If it is determined in step S13 that the memory storage amount is greater than or equal to the maximum set value Rmax, in step S14, all servos are turned off, the laser is turned off (OFF), data reading is stopped, and a servo in a complete energy saving mode is set. Set to OFF mode. Thereafter, the process returns to step S1, and thereafter, the processes of the above steps are repeated.
[0053]
FIG. 3 is a time chart for explaining the operation of the MD reproducing apparatus of the present embodiment. In FIG. 3, L1 is a line indicating the rotational speed of the spindle motor 8 (the rotational speed of the mini disk 1), L2 is a line indicating the operation of the spindle motor servo circuit 511, and L3 is an operation of a servo circuit other than the spindle motor servo. Line L4 is a line indicating turning on / off of the laser, and L5 is a line indicating a memory storage amount.
[0054]
Hereinafter, the temporal operation of the MD playback apparatus will be described with reference to this time chart. First, in the servo OFF state at the time of reproduction, the spindle motor 2 is started when the memory storage amount of the shock proof memory 8 decreases to Rmin, and the rotational speed of the mini disk 1 is increased. When the rotational speed reaches fS necessary for servo pull-in, the laser is turned on and the servo is turned on, and reading of data written on the mini disk 1 is started at a constant rotational speed.
[0055]
Thereafter, during the period t1, reading with the servo ON is continued, and then the spindle motor servo circuit 511 is turned OFF. Even if the spindle motor servo circuit 511 is turned off, the mini disk 1 and the spindle motor 2 rotate due to inertia, so that the rotational speed gradually decreases as indicated by the line L1. The data is read while the servo circuit other than the spindle motor servo is operated while is kept lit.
[0056]
After the elapse of the period t2, when the memory storage amount of the shock proof memory 8 reaches Rmax, the laser is turned off, and all servo circuits other than the spindle motor servo are turned off, and the servo OFF state mode of the intermittent servo is entered. This is a further power saving mode. It should be noted that when the memory storage amount of the shock proof memory 8 reaches Rmax, the rotational speed of the spindle motor 2 is usually equal to or higher than the lower limit fL at which the servo is restarted. As described above, the MD reproducing apparatus saves power by repeating the operation of the time chart described above.
[0057]
In the above embodiment, the portable MD playback device has been described as an example. However, the present invention is not limited to the MD playback device, and the memory is configured to store the information signal read from the optical disk in the memory. By reading out information signals from the memory at a speed slower than the writing speed with respect to the recording medium, the present invention can be widely applied to optical disk reproducing apparatuses that reproduce optical disks while accumulating information signals in the memory.
[0058]
【The invention's effect】
As described above, according to the present invention, after the rotational speed of the spindle motor that rotates the optical disk reaches a predetermined rotational speed, the servo means of the spindle motor is stopped after a predetermined time has elapsed. Since the system controller that controls the information recorded on the optical disc can be demodulated, the servo means of the spindle motor is stopped when the number of revolutions of the spindle motor that rotates the optical disc reaches a predetermined number of revolutions. Thus, while the optical disk is rotated by inertia, power consumption is reduced, and power saving can be achieved.
[0059]
Further, according to the present invention, the optical disk is rotated at a constant speed for a time during which a data signal is read from the rotating optical disk, that is, a time shorter than the servo ON time of the spindle motor servo means. The servo means is turned off, the optical disk is rotated by inertia, and while the rotation speed is detected by the rotation speed detection means, a reproduction clock is generated by the data signal from the RF amplifier, the reproduction clock is controlled, and the RF amplifier The data signal read from the optical disk is continuously tracked by the PLL circuit while the data signal read out from the optical disk continuously with a time interval extending can be continuously demodulated by the demodulating means. When the motor speed reaches the specified speed, the spindle motor servo Is stopped and the data signal from the optical disk can continue to be demodulated while the optical disk is rotating due to inertia, and while the optical disk is rotating due to inertia, power consumption is reduced and power consumption is reduced. Can be planned.
[0060]
Further, according to the present invention, the data signal read from the optical disk is stored in the memory, and when this storage amount reaches a predetermined amount, it is stored in the memory in the same manner as in the normal intermittent servo operation. Operation of components (optical pickup, RF amplifier, servo control signal generation means, optical pickup servo means, other servo related means, PLL circuit) other than the circuit that reads data, decompresses it, and converts it into a voice / music signal By stopping, power consumption can be reduced.
[0061]
In addition, according to the present invention, the optical disk playback device is used for portable purposes when the storage amount of data stored in the memory does not reach the predetermined amount due to the orientation of the portable device. This prevents the data read-inhibiting operation due to the decrease in the number of rotations and exceeding the logic range of the PLL circuit, and the data can be securely stored in the memory.
[0062]
In addition, according to the present invention, when it is determined that there are many errors in the demodulated data signal, in order to read the data signal more reliably, the reading of the optical disk by the normal inertia is not continued, but the spindle motor By restarting the servo means and performing reading in a state where the spindle motor servo is applied, it is possible to cope with the amount of data stored in the memory not being insufficient.
[0063]
Further, according to the present invention, when the number of revolutions of the spindle motor has reached the predetermined number of revolutions, the demodulated data signal has many errors before the predetermined time has elapsed after the number of revolutions is detected by the revolution number detecting means. If it is determined, the spindle motor servo means can be driven without being turned off, and a reliable reading of the data signal can be performed so that the amount of data stored in the memory does not become insufficient. it can.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an MD playback apparatus according to an embodiment of the present invention.
FIG. 2 is a flowchart for explaining the operation of the MD playback apparatus of the embodiment.
FIG. 3 is a time chart for explaining the operation of the MD playback apparatus of the embodiment.
[Explanation of symbols]
1 Mini-disc (optical disc)
2 Spindle motor
3 Optical pickup
6 RF amplifier
8 Shock proof memory
11 System controller
14 Power supply
51 Spindle motor drive circuit (spindle motor drive means)
71 Signal processing circuit (demodulation means)
72 Servo control signal generation circuit (servo control signal generation means)
73 PLL circuit
74 Voice expansion circuit (expansion processing means)
511 Spindle motor servo circuit (spindle motor servo means)
512 Rotational speed detection circuit (Rotational speed detection means)
521 Optical pickup servo circuit (optical pickup servo means)

Claims (6)

In an optical disk reproducing apparatus for reproducing information recorded on an optical disk, after a predetermined time has elapsed after the rotation speed of the spindle motor that rotates the optical disk reaches a predetermined rotation speed, the servo means of the spindle motor is stopped, An optical disk reproducing apparatus comprising a system controller that performs control so that information recorded on the optical disk can be demodulated after this. An optical pickup that optically reads information recorded on the optical disc and converts it into an electrical signal, an RF amplifier that generates a data signal and a servo signal based on an output signal of the optical pickup, a spindle motor that rotates the optical disc, Servo control signal generating means for generating servo control signals for controlling the spindle motor and the optical pickup based on the servo signals, and optical pickup servo means for servo-controlling the optical pickup based on the servo control signals A spindle motor servo means for servo-controlling a spindle motor based on the servo control signal, a demodulating means for demodulating recorded information on the optical disk based on an RF signal which is a data signal from the RF amplifier, and the demodulated Stored recording information Memory, decompression processing means for reading out a data signal of recording information from the memory and performing processing including decompression / error correction, spindle motor driving means for driving and controlling the spindle motor, and detecting the rotational speed of the spindle motor Rotation speed detecting means, and a PLL circuit for generating a reproduction clock based on the data signal from the RF amplifier and controlling the reproduction clock so that the data signal from the RF amplifier can be read. In the optical disk reproducing apparatus, the spindle motor driving means is operated to detect that the spindle motor has reached a predetermined rotational speed, and after the predetermined time has elapsed, the spindle motor is detected. The servo means is stopped, and after this, the optical data is picked up by the optical pickup. Continue reading the data signal from the disk, the optical disk reproducing apparatus characterized by comprising a system controller for controlling to continue demodulated by the demodulating means while tracking by the PLL circuit. After the spindle motor driving means is activated and the spindle motor rotation means has detected that the spindle motor has reached a predetermined rotational speed, the spindle motor servo means is stopped after a predetermined time has elapsed. Thereafter, the data signal from the optical disk is continuously read by the optical pickup, demodulated by the demodulating means while being followed by the PLL circuit, and the demodulated data signal is stored in the memory. When the signal reaches a predetermined amount, supply of power to the optical pickup, the RF amplifier, the servo control signal generation means, the optical pickup servo means, other servo related means, and the PLL circuit is stopped. The optical controller according to claim 2, further comprising a system controller that performs control. Click playback device. After the spindle motor driving means is activated and the spindle motor rotation means has detected that the spindle motor has reached a predetermined rotational speed, the spindle motor servo means is stopped after a predetermined time has elapsed. After that, when the data signal from the optical disk is continuously read by the optical pickup, and demodulated by the demodulating means while being followed by the PLL circuit, the demodulated data signal is stored in the memory, When the rotational speed of the optical disk has decreased to a preset rotational speed before the storage amount reaches a predetermined amount, the spindle motor servo means until the storage amount in the memory reaches a predetermined amount. And a system controller that performs control to store a predetermined amount of data in the memory. The optical disk reproducing apparatus according to claim 2, wherein the door. After the spindle motor driving means is operated and the rotation speed detecting means detects that the rotation speed of the spindle motor has reached a predetermined rotation speed, the spindle motor servo means is stopped after a predetermined time has elapsed. Thereafter, when the data signal from the optical disk is continuously read by the optical pickup and demodulated by the demodulating means while being followed by the PLL circuit, the demodulated data is demodulated if it is to be stored in the memory. A system controller that controls the spindle motor servo means to operate again even if the rotational speed of the optical disk does not decrease to a preset rotational speed when it is determined that there are many errors in the data signal. The optical disk reproducing apparatus according to claim 2, wherein After the spindle motor driving means is operated and the rotation speed detecting means detects that the rotation speed of the spindle motor has reached a predetermined rotation speed, the demodulated data signal is converted into a demodulated data signal before a predetermined time elapses. 3. The optical disk according to claim 2, further comprising a system controller that performs control so that the spindle motor servo means is driven without stopping when it is determined that there are many errors. Playback device.

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