KR19980064265A - Information playback device - Google Patents

Abstract

An information reproducing apparatus is provided, which includes measuring means for measuring the intensity of a signal read from an information recording medium such as a disc, storage means for temporarily storing information reproduced at a first transfer rate, and a first Means for reading information stored in the storage means at a second transfer rate lower than the transfer rate, so that the maximum speed of the information storage medium is set in accordance with the jitter strength measured by the measuring means.

Description

Information playback device

The present invention relates to a reproduction apparatus for reproducing information from a recording medium such as an optical disc, a magnetic optical disc or a video tape.

In an apparatus for reading information by using a relative linkage between the information recording medium and the information reading head, such as in a reproducing apparatus for an optical disc, a magneto optical disc, or a video tape, the deformation, misalignment, recording medium, and read head of the recording medium. Irregular rotation of the drive unit for driving the relative noise generates noise called jitter in the reproduction signal. Therefore, since jitter is generated due to the relative linkage between the recording medium and the deformation of the recording medium, the jitter becomes large in proportion to the relative speed of the read head and the read speed.

On the other hand, as the recording medium and the reproduction apparatus advance, the recording density of the recording medium increases and the amount of information that can be read within a unit time increases. However, the amount of information required for unit time such as audio information and video information reproduced on the TV screen is constant. Therefore, information can be read faster than the use speed, especially in the field of audio and video devices. By using the speed difference, the information is temporarily stored in a storage unit such as RAM at high speed transfer. The information is read from the storage at low speed transmission and then supplied to the audio and video portions.

When the storage unit is used as a buffer of information, even if the reading operation of the information is temporarily increased due to the omission of the read head or the positional shift of the recording medium, if the reading operation is stored again before the information stored in the storage unit becomes empty, The information is continuously supplied to the audio and video portions without interruption. The structure that provides the disc reproducing apparatus with shock proof performance is called an electric shock probe (ESP). The storage unit for temporarily storing information is called seismic memory.

In an optical disc reproducing apparatus having such a seismic function, digital data is read and stored in correspondence with control data recorded on the optical disc. Alternatively, the optics are rearranged corresponding to the control data. Therefore, if the control data cannot be read continuously, the data cannot be reproduced correctly. Alternatively, the continuity of the audio output cannot be maintained because the data cannot be connected completely. Therefore, in a system in which control data is recorded together with audio data and video data on a recording medium such as a disc, even if audio data and video data are read correctly, the data is seismic memory when the control data cannot be read continuously. Cannot be stored in

Audio digital data is error corrected with Cross Interleved Reed Solomon Code (CIRC). On the other hand, in the case of control data, only the CRC error correction code is added. Therefore, the reliability of the control data is lower than that of the audio digital data. This structure has a lot of difficulties in the seismic processing of large jitter disks. In the case of discs with large jitter, since the reading level of high frequency components (as in a short pit read signal) is usually low, when the reproduction speed of an optical disc is increased, S / N (signal The noise gets worse. Therefore, control data cannot be read correctly.

In order to easily read out the control code, it is necessary to reduce the playback speed. In this case, however, the data reading speed is reduced. Therefore, the seismic function deteriorates and the seismic performance is lowered.

It is an object of the present invention to provide a reproducing apparatus which is not adversely affected by jitter.

It is another object of the present invention to provide a reproducing apparatus which automatically measures jitter and reads data at the maximum reading speed allowed in response to the jitter intensity.

The present invention provides reproducing means for reproducing information read by the reading means from the recording medium, drive means for driving the recording medium relative to the reading means, measuring means for measuring jitter of the information reproduced by the reproducing means, and Jitter measured by the storage means for temporarily storing the information recorded on the recording medium at one transfer rate, the reading means for reading the information recorded on the recording medium at a second transfer rate lower than the first transfer rate, and the measuring means Is an information reproducing apparatus including drive control means for controlling the speed of the drive means.

The present invention provides reproducing means for reproducing information read by the reading means from the recording medium, drive means for driving the recording medium relative to the reading means, measuring means for measuring jitter of the information reproduced by the reproducing means, and Storage means for temporarily storing information recorded on the recording medium at one transfer rate, reading means for reading information recorded on the recording medium at a second transfer rate lower than the first transfer rate, and the reproducing means reproduces the recording medium. And a drive control means for causing the measurement means to measure jitter a plurality of times while controlling the speed of the drive means in accordance with the measured jitter.

Since the maximum speed of the spindle motor is set in correspondence with the jitter value of the disk used, data can be read back at the maximum speed allowed as long as no read error occurs. In addition, jitter is measured at intervals of a predetermined period or at intervals of a predetermined number of tracks during data reproduction. Using the measured jitter, the maximum speed of the spindle motor is set. Thus, data can be read at the maximum speed allowed as long as no read error occurs.

The above objects and features of the present invention will become apparent from the following detailed description and claims with reference to the accompanying drawings.

1 is a block diagram showing the structure of a DC player according to the present invention;

2 is a schematic diagram illustrating a frame structure of a CD.

3A and 3B are schematic diagrams illustrating subcoding data of a CD.

4A and 4B are schematic diagrams illustrating sub-Q data of a CD.

5 is a schematic diagram illustrating TOC data of a CD.

6A and 6B are flowcharts showing processing of the ESP function.

7 is a flow chart illustrating a process in retry mode.

8 is a schematic diagram illustrating a process of setting a frame inspection reference value.

9 is a schematic diagram illustrating continuity determination criteria.

10 is a flowchart illustrating a speed setting process of the spindle motor.

11 is a schematic diagram illustrating a speed setting process of a spindle motor.

12 is a block diagram showing an example of a jitter measuring device.

13 is a flowchart illustrating an example of a process of setting a maximum rotational speed of a spindle motor.

14 is a flowchart showing another example of the process of setting the maximum rotational speed of the spindle motor.

15 is a schematic diagram showing jitter intensity table data.

16 is a flowchart showing a jitter measurement process at predetermined time intervals.

FIG. 17 is a flowchart showing a jitter measurement process for each interval of a predetermined number of tracks. FIG.

18 is a flowchart illustrating an access process in a track jumping operation.

Explanation of symbols for the main parts of the drawings

1: optical disc

2: spindle motor

12: optical servo processing unit

13: EFM demodulator

14: Subcode processing

15: error correction unit

17: deinterleaving part

18: spindle servo signal processing unit

23: auto sequencer

25: phase comparator

26: driver

30: DRAM

31: CPU

32: D / A Converter

34: clock generator

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. 1 is a block diagram showing a CD reproducing apparatus according to the present invention. Referring to FIG. 1, information is read by the optical head 3 in a state where the disk 1 is rotated and driven by the spindle motor 2. The optical head 3 irradiates the disk 1 with laser light, and reads audio information recorded in the form of a pit on the disk 1 in correspondence with the reflected light, for example.

Since data is read from the disk 1 in the above-described manner, the optical head 3 serves as a laser output means as a laser output device 3d composed of a laser diode 3c, a polarizing splitter, a quarter wave plate, and a laser output end. The objective lens 3a and the detector 3b which detects reflected light are provided.

The objective lens 3a is supported by the biaxial actuator 4 in such a way that the objective lens 3a is moved in the radial direction (tracking direction) of the disk and the contact direction (focusing direction) of the disk. The optical head 3 is movable in the radial direction of the disk by a thread mechanism 5.

The information detected from the disc 1 by the optical head 3 in the reproduction operation is supplied to the RF amplifier 7. The amplified signal output from the RF amplifier 7 is supplied to the RF equalizing unit 9 of the digital signal processing processor 9 (hereinafter referred to as DSP).

The RF equalizing unit 9 performs arithmetic processing on the received information, and extracts a reproduction RF signal (EFM signal), a tracking error signal TE, a focus error signal FE, and the like.

The reproduced RF signal is supplied to the EFM demodulator 13 as a binary signal, that is, an EFM signal (Eight-Fourteen Modulation signal) through the asymmetric compensation circuit 10 and the RF-PLL circuit 11. The RF-PLL circuit 11 performs a so-called PLL operation, generates a reproduction clock in synchronization with the EFM signal, and supplies the reproduction clock as a clock for decoding processing to the EFM demodulator 13.

The EFM demodulator 13 demodulates the EFM signal and extracts a subcode component (to be described later). The subcode processing unit 14 decodes the subcode data (for example, the subcode processing unit 14 extracts the subcode Q data, for example).

The subcode data is supplied to the CPU 31 which functions as a system controller of the CD player via the CPU interface unit 19 (hereinafter referred to as CPU-IF).

Data demodulated by the EFM demodulator is recorded in the ECC-RAM 16. The ECC-RAM 16 performs CIRC decoding processing through the error correction unit 15 which performs read / write processing. In other words, the ECC-RAM 16 performs C1 correction processing and C2 correction processing.

Deinterleaving circuit 17 deinterleaves the CIRC-decoded data and modulates the data as digital audio data sampled at 44.1 kHz and quantized to 16 bits. The digital audio data DT is temporarily stored in the buffer memory 30 under the control of the memory controller 29. Data (digital audio data DT) read out from the buffer memory 30 at a predetermined time is converted by the D / A converter 32. The resulting analog audio signal S _A is supplied via the terminal 33 to the audio amplifier as an audio signal of, for example, the right channel and the left channel.

The buffer memory 30 is composed of a D-RAM. The buffer memory 30 stores digital audio data DT for about three seconds as an audio output. The buffer memory 30 may be configured other than the D-RAM.

Electrical buffering (ESP) functionality can be achieved using the buffer memory 30.

That is, the rotational speed of the disk 1 is adjusted by the spindle motor 2. Signal processing performed from the optical disc 3 to the DSP 8 is performed at high speed. The decoded digital audio data DT is recorded in the buffer memory 30.

On the other hand, under the control of the memory controller 29, data is read from the buffer memory 30 at a normal speed. Thus, the audio signal is reproduced and output at normal speed.

Since there is a difference between the write bit rate and the read bit rate of the buffer memory 30, a certain amount of data is always stored in the buffer memory 30. Therefore, even when the optical head 3 temporarily stops reading data from the disk 1 due to disturbance, data can be read from the buffer memory 30, so that data is not interrupted. The optical head 3 resumes the read operation from an appropriate position while reproducing the stored data.

As the above-described subcode data, subcode information (i.e., TOC and address data) recorded on the disc 1 is extracted and supplied to the CPU 31. Thus, the CPU 31 checks the continuity of the data.

If the error correction unit 15 cannot correct the error by the C1 and C2 correction processing, the error correction unit 15 outputs a C2PO signal indicating such a situation. The C2PO signal is supplied to the CPU 31. As a result, the CPU 31 monitors the occurrence of the error. In addition, the score signal is supplied from the DSP 8 to the CPU 31. This score signal represents the synchronization of data recorded in the buffer memory 30.

The focus error signal FE and the tracking error signal TE obtained by the RF equalizing unit 9 are supplied to the optical system servo signal processing unit 12.

The optical system servo signal processing unit 12 generates a servo drive signal in accordance with the tracking error signal TE, the focus error signal FE, or the track jump command, the access command, or the like received from the CPU 31 via the CPU-IF 19.

The optical system servo signal processing unit 12 generates a servo signal as a PWM modulation signal in accordance with the focus error signal FE and supplies this servo signal to the servo driver 26. The servo driver 26 generates a focus drive signal based on the received PWM modulated signal. The focus drive signal is supplied to the focus coil of the biaxial mechanism 4. In other words, the objective lens 3a is driven in the focus direction based on the focus drive signal.

When the focus search operation is performed, the optical system servo signal processing unit 12 turns off the focus servo loop and supplies a PWM modulation signal of a voltage value to be generated to the servo driver 26 according to the search voltage under the control of the CPU 31. do. The servo driver 26 supplies the focus search voltage as a focus drive signal to the focus coil of the biaxial mechanism 4 based on the supplied PWM modulated signal.

In addition, the optical system servo signal processor 12 generates a servo signal as a PWM modulated signal in accordance with the tracking error signal TE. This servo signal is supplied to the servo driver 26. The servo driver 26 generates a tracking drive signal based on the received PWM modulated signal and supplies the tracking drive signal to the tracking coil of the biaxial mechanism 4. In other words, the servo driver 26 drives the objective lens in the tracking direction based on the tracking drive signal.

The optical system servo signal processing unit 12 extracts a low frequency component from the tracking error signal TE to generate a thread servo signal as a PWM modulation signal, and supplies this thread servo signal to the servo driver 26. The servo driver 26 generates a thread drive signal based on this servo signal to drive the thread mechanism 5.

As described above, in the RF-PLL circuit 11, a reproduced clock which is synchronized with the reproduced RF signal is generated by supplying the reproduced EFM signal to the PLL circuit. The reproduced clock is used for various processing such as EFM decoding. The reproduced clock is a signal synchronized with the rotation of the disc 1. The spindle servo signal processing unit 18 of the DSP 8 compares the reproduced clock with the reference clock generated by the master clock to obtain the difference as the spindle error signal SPE.

Typically, a drive signal for driving the spindle motor based on the spindle error signal SPE is generated. However, in the present embodiment, the DSP 8 used a wide-capture method. That is, the system clock is fixed by the rotation of the spindle motor 2. Therefore, the signal processing in the DSP 8 is performed by the clock.

For this reason, the spindle error signal SPE received from the spindle servo signal processing unit 18 is supplied to the voltage controlled oscillator VCO 21 through the low pass filter 20 which limits the band. In other words, the spindle error signal SPE is used as the control voltage of the VCO 21.

Since the spindle error signal SPE changes in accordance with the rotational speed of the spindle motor 2, the VCO 21 oscillates in accordance with the rotational speed of the spindle motor 2. The oscillated output signal of the VCO 21 is supplied to the clock generator 34. Clock generator 34 generates the master clock of the DSP system in response to the oscillated output signal of VCO 21. This master clock CK is used as a reference clock of the RF-PLL circuit 11. In addition, the master clock CK is a processing reference in the DSP 8. Therefore, the entire signal processing system of the DSP 8 performs processing following the rotational speed of the spindle motor 2.

Since the DSP 8 operates at a clock corresponding to the rotational speed of the spindle motor 2, while the spindle motor 2 is accelerated, it cannot be read by the clock under normal conditions, but the read data can be decoded. For example, when the disk 1 is chuk and the spindle motor 2 is started, data can be read quickly.

The output signal of the VCO 21 is frequency-divided by the 1 / M frequency divider 22 and then supplied to the phase comparator 25. On the other hand, the frequency of the system clock received from the crystal oscillator 28, which is a crystal clock generator, is divided by the 1 / N frequency divider 22 and then supplied to the phase comparator 25. The division ratios M and N of the 1 / M frequency divider 22 and the 1 / N frequency divider 24 are controlled by a command from the CPU 31 via the automatic sequencer 23.

When the phase comparator 25 compares the phase of the output signal of the VCO 21 with the phase of the system clock received from the oscillator 28, a drive control signal of the spindle motor 2 is generated. The drive power according to the drive control signal from the LPF and the spindle driver 27 is supplied to the spindle motor 2. Thus, the spindle motor 2 is controlled to rotate at a predetermined CLV speed.

When the division ratios of the 1 / M frequency divider 22 and the 1 / N frequency divider 24 are set to a specific value, the rotational line speed of the spindle motor 2 is set at standard speed (1.0 times speed), 1.5 times speed, 2 times speed, and the like. It can be controlled at any speed. That is, the CPU 31 controls the automatic sequence 23 through the CPU-IF 19 to change the rotational speed of the spindle motor 2. Further, by the FG (frequency generator) pulse received from the spindle motor 2, the spindle motor 2 can be controlled to rotate at a CAV (constant angular velocity).

Next, the TOC (contents table) and subcodes recorded in the lead-in area of the disc 1 (CD-DA: CD-digital audio) will be described.

The minimum recording unit of CD-DA is one frame. One block (one subcode frame) is composed of 98 frames.

2 shows the structure of one frame. One frame consists of 588 bits. The first 24 bits of one frame are synchronization bits, and the next 14 bits are subcode regions. This subcode area is followed by data and parity.

One block consists of 98 frames. By correcting the subcode data obtained from the 98 frames, one block of subcode data as shown in Fig. 3A is formed.

The first and second frames (frames 98n + 1 and 98n + 2) of the 98 frames are synchronization patterns. The third to 98th frames (frames 98n + 3 to 98n + 98) are channel data. In each frame, subcode data of channels P, Q, R, S, T, U, V, and W (each of which consists of 96 bits) is formed.

To access each frame, channels P and Q are used. However, channel P represents the rest between tracks. However, the accessing operation is controlled by channels Q ₁ through Q ₉₆ . 3B shows the data structure of the channel Q consisting of 96 bits.

Four bits Q ₁ to Q ₄ are control data. The four bits Q ₁ to Q ₄ are used to identify audio channel numbers, emphasis, CD-ROM, and the like.

In other words, 4-bit control data is defined as follows.

0 *** ... 2-channel audio

1 *** ... 4-channel audio

* 0 * ... CD-DA

* 1 ** ... CD-ROM

** 0 * ... digital copy disabled

** 1 * ... digital copy available

*** 0 ... no pre-emphasis

*** 1 * ... Pre-emphasis present

Four bits Q ₅ to Q ₈ represent an address. These four bits are the control bits of the sub Q data.

If the four bits Q ₅ to Q ₈ representing the address are 1, the subsequent sub Q data of Q ₉ to Q ₈₀ represent audio Q data. When four bits Q ₅ to Q ₈ are 100, subsequent sub Q data of Q ₉ to Q ₈₀ represent video Q data.

72 bits Q ₉ to Q ₈₀ are sub-Q data. The remaining bits Q ₈₁ through Q ₉₆ are CRC.

The sub-Q data recorded in the lead-in area is TOC information.

In other words, the sub-Q data of 72 bits Q ₉ to Q ₈₀ of the Q-channel read out from the lead-in area has the information as shown in FIG. 4A. The sub-Q data has data composed of 8 bits.

First, the track number is recorded. In the lead-in area, the track number is set to zero.

Next, a POINT is recorded. In addition, MIN (minutes), SEC (seconds), and FRAME (frame number) are recorded as the elapsed time on the current track.

In addition, PMIN, PSEC, and PFRAME are recorded. The meaning of PMIN, PSEC, and PFRAME is determined by the value of POINT.

If the value of POINT falls between 1 and 99, this value is the track number. In this case, the starting point of the track with the track number is recorded as minutes PMIN, seconds PSEC and frame number PFRAME.

If the value of POINT is A0, the track number of the first track is recorded as PMIN. In addition, according to the value of PSEC, CD-DA, CD-I, and CD-ROM (XA specification) are distinguished.

If the value of POINT is A1, the track number of the last track is recorded as PMIN.

If the value of POINT is A2, the starting point of the lead-out area is recorded as SMIN, PMIN, and PFRAME.

In the case of a disc having six tracks, the data shown in Fig. 5 is recorded as a TOC of sub-Q data. As shown in FIG. 5, all track numbers TNO are zero.

The block number represents one unit of Q data number read as block data of 98 frames.

Three consecutive blocks of TOC data have the same content.

As shown in Fig. 5, when the value of the POINT belongs to 1 to 6, the starting points of the tracks # 1 to # 6 are recorded as PMIN, PSEC, and PFRAME.

If the value of POINT is A0, track number 1 is recorded as PMIN. The value of PSEC distinguishes the type of disc. If the disk is a CD-DA, the value of PSEC is zero. If the disc is a CD-ROM (XA specification), the value of PSEC is 20. If the disc is CD-I, the value of PSEC is 10.

If the value of POINT is A1, the track number of the last track is recorded as PMIN. If the value of POINT is A2, the starting point of the read-out is recorded as PMIN, PSEC, and PFRAME.

After block n + 27, the contents of blocks n to n + 26 are repeatedly recorded.

In the tracks # 1 to #n and the lead-out area for data such as a music program on the disc 1, the recorded sub-Q data has the information shown in Fig. 4B.

First, the track number is recorded. In tracks # 1 to #n, one of track numbers 1 to 99 is recorded. In the lead-out area, the track number is AA.

Next, information capable of subdividing each track is recorded as an index.

The elapsed time in the current track is recorded as MIN (minutes), SEC (seconds), and FRAME (frame number).

In addition, an absolute address is recorded as minutes (AMIN), seconds (ASEC), and frame number (AFRAME).

The TOC and subcodes are formed as above. Thus, the address of the disc is recorded as AMIN, ASEC, and AFRAME every 98 frames.

98 frames (one block) are referred to as one subcoding frame. Thus, the value of AFRAME falls in the range of 0 to 74. In the frame checking process (to be described below), the data continuity is checked for each subcoding frame.

In the case of the CD player according to the present embodiment, the buffer memory 30 is used to perform the ESP function. Next, processing in the reproduction mode of the CPU 31 in the case of executing the ESP function will be described with reference to FIGS. 6 and 7.

In order to execute the ESP function when reproducing data from the disc 1, in the CD player according to this embodiment, the CPU 31 reads the data at a predetermined transfer rate and checks the missing state of the read data. Audio signals are continuous.

In addition, the space of the buffer memory 30 is monitored in accordance with the state of the amount of data remaining in the buffer memory 30, and the CPU 31 causes an error in order to prevent the poor quality data from being output as a reproduced audio signal. Check the correction status.

6 and 7 are flowcharts showing processing of the CPU 31 including frame checking processing and error checking processing.

When the disc 1 is loaded at the position of the optical head 3 (so that the data can be reproduced), the CPU 31 causes the optical head 3 to read TOC data recorded on the innermost periphery of the disc. Let's do it.

In other words, the CPU 31 causes the optical head 3 to reproduce the lead-in area so as to read the TOC data executed by the subcode processing unit 14. The CPU 31 can control the reproduction operation by obtaining the address of the individual tracks of the disc 1 loaded by the TOC data.

After the start of the reproducing operation, the CPU 31 performs processing for the ESP operation as shown in FIG.

In step 601, the CPU 31 always monitors the amount of data stored in the buffer memory 30.

In this embodiment, the result of monitoring the amount of data stored in the buffer memory 30 is used for frame checking processing, error checking processing, and speed setting of the spindle motor (to be described later).

As a result of monitoring the amount of data stored in the buffer memory 30, if no data exists in the buffer memory 30, the reproduced audio output becomes silent. In this case, the flow proceeds from step F102 to step F103. In step F103, the CPU 31 performs error processing.

If data exists in the buffer memory 30, the flow advances to step F104. In step F104, the CPU 31 sets a reference value of the frame checking process. In the present embodiment, the CPU 31 sets the reference value FC in accordance with the amount of data stored in the buffer memory 30.

Next, the reason for setting the frame checking reference value FC in accordance with the amount of data stored in the buffer memory 30 will be described.

If the continuity of the read data is lost by track jump due to disturbance, the CPU 31 reads back the data so that the continuity of the data can be restored. Therefore, the CPU 31 writes data to the buffer memory 30 so that the continuity of the reproduced audio output is maintained. Therefore, in the reproduction mode, the CPU 31 continuously checks the frames and checks the read data.

Although it is desirable to check the continuity of the read data as accurately as possible, it is necessary to prevent the data stored in the buffer memory 30 from being consumed. In other words, each time the continuity of the read data is lost, if the retry operation is performed, the data stored in the buffer memory 30 is consumed. Thus, when the continuity of the read data is strictly checked, the number of retry operations is increased. As a result, the amount of data stored in the buffer memory 30 decreases, so that the seismic characteristic is deteriorated. Track jumps performed for retry operations degrade the quality of the reproduced audio signal and increase power consumption. In other words, the strict continuity checking process conflicts with the quality of the reproduced audio signal.

In the case where data is lost in the order in which the user does not recognize the interruption of the reproduced audio signal, it is assumed that continuity is not lost. Therefore, the CPU 31 cannot perform the retry operation, thereby protecting the seismic characteristics from deterioration. Strictly speaking, however, when such an interruption occurs, the user may hear the choked sound. Therefore, it is desirable to perform as many retries as possible in order to connect sound data correctly.

In order to do so, according to the present invention, the CPU 31 corresponds to the amount of data stored in the buffer memory 13 in order to maintain the continuity of the data as accurately as possible and to protect the buffer memory 13 from deterioration of the seismic function. Change the criteria for determining whether an interruption in the system occurs.

8 and 9 show examples of the set frame check reference value FC.

When the buffer memory 30 is full (data amount = 100%), data for 3 seconds may be stored. If the amount of data stored in the buffer memory 30 is 50% or more as shown in Fig. 8 (thus, data can be output for 1.5 seconds or more), the reference value FC is 5 (subcoding frame). If the amount of data stored in the buffer memory 30 is 50% or less (thus, data for 1.5 seconds or less can be output), the reference value FC is 40 (subcoding frame).

The frame check reference value FC is a value indicating that no data loss is assumed to occur when the amount of lost data is less than or equal to the FC subcoding frame. In other words, when the frame check reference value FC is small, the checking process is strictly performed.

That is, if the buffer memory 30 has sufficient space, the reference value FC is set to 5 to strictly perform the frame checking process. In this case, even when the retry operation is performed a proper number of times, since the time error is large, the seismic characteristics are not significantly affected. Thus, even when the read data is interrupted, due to the retry operation, the continuity of the data can be mostly recovered.

On the other hand, if the buffer memory 30 does not have enough space (that is, if the space of the buffer memory 30 corresponds to the amount of data for 0 to 1.5 seconds), the CPU 31 sets the reference value FC to 40. The frame checking process is performed roughly.

If the retry operation is performed a plurality of times, a situation of the buffer memory 30 having no space may occur due to the seismic characteristics. In this case, since the frame checking process is roughly performed, the retry operation is not frequently performed. Therefore, the situation where the buffer memory 30 has no space can be prevented as much as possible. That is, at this point, even if a few minutes of audio signal deficiency is allowed to some extent, the absence of sound is prevented.

After the CPU 31 sets the frame check reference value FC in step F104 (in Fig. 6), the flow advances to step F105. In step F105, the CPU 31 determines whether the buffer memory 30 is full. If the buffer memory 30 is full, the CPU 31 must temporarily stop writing data to the buffer memory 30. At this point, the flow advances to step F106. In step F106, the CPU 31 performs a sound coupling process for writing subsequent data at a predetermined timing in the retry mode.

In this example, the CPU 31 adjusts the rotational speed of the spindle motor 2 so that the buffer memory 30 does not become full. Therefore, in the normal state, in step F105, the CPU 31 does not determine whether the buffer memory 30 is full.

If the buffer memory 30 is not full, the flow advances to step F107. In step F107, the CPU 31 performs a frame checking process.

In the process shown in Fig. 6, since the sub Q data read in step F112 is stored as variable SUBLAST, the CPU 31 compares the current sub Q data read in step F107 with the last sub Q data stored as variable SUBLAST. do.

As described above, if the continuity of data is not lost at all, the difference between the current address and the final address is one subcoding frame. However, the drop of data up to five subcoded frames does not affect the reproduced audio signal.

Therefore, in step F108, if the difference between the current address and the last address is within the frame check reference value FC, the CPU 31 determines that the continuity is smooth.

That is, as shown in Fig. 9, when the address of the current sub-Q data is the same as the address value to which the last sub-Q data SUBLAST and the frame check reference value FC are added, the CPU 31 judges that the continuity is smooth. .

As described above, since the frame check reference value FC is set corresponding to the space of the buffer memory 30, when the space of the buffer memory 30 is large, the continuity is strictly checked. On the other hand, if the space of the buffer memory 30 is small, the continuity is roughly checked.

If the dropped data amount exceeds the frame check reference value FC as a result determined in step F108, the CPU 31 determines that the continuity of the data is lost. Thus, the flow advances to step F109. In step F109, the CPU 31 performs a read retry operation.

If the continuity is good as a result determined in step F108, the flow advances to step F110. In step F110, the CPU 31 determines whether the error checking process is performed.

The error checking process is performed by detecting the amount of data that cannot be corrected (i.e., the number of occurrences of C2PO). If the number of occurrences of C2PO exceeds the predetermined value set as the error level, the CPU 31 determines that the read data of the current subcoding frame does not satisfy the predetermined quality level. Thus, the CPU 31 performs a read retry operation.

The CPU 31 performs such an error checking process only when the amount of data stored in the buffer memory 30 is 80% or more as a result determined in step F110. In other words, if there is enough space in the buffer memory 30, the flow advances to step F113. In step F113, the CPU 31 determines whether the current data has been read in the normal reproducing operation or the retry mode (described later).

In the normal reproducing operation, in step F114, the CPU 31 sets the error level as an error check criterion to zero. The error check level 0 indicates that the CPU 31 judges that the result of the error checking process is smooth only when the number of occurrences of C2PO is zero.

On the other hand, in the retry mode, the CPU 31 changes the check criteria at various steps. That is, in the first retry process, the CPU 31 sets the error level to zero. In the second retry process, the CPU 31 sets the error level to five. That is, the CPU 31 allows generation of C2PO up to five times.

In the third retry process, the CPU 31 does not set the error level. In other words, the CPU 31 does not actually perform the error checking process.

In the case where the frame check reference value is set corresponding to the space of the buffer memory 30, the error level changes in several steps, so that the space of the buffer memory 30 becomes zero to obtain high quality reproduced data. Meets contradictory conditions to prevent

In step F116, the CPU 31 performs an error checking process corresponding to the error level set in step F114 or F115. That is, the CPU 31 compares the number of occurrences of C2PO generated in the error correction process with respect to the subcoding frame with the error level. If the number of occurrences of C2PO exceeds the error level, the CPU 31 determines that the predetermined quality of the data is not satisfied. Thereafter, the flow advances to step F117. In step F117, the CPU 31 performs a retry operation.

If the result of the frame checking process is smooth and the result of the color checking process is smooth, the flow proceeds to step F111. In step F111, the CPU 31 writes data (digital audio data) to the buffer memory 30. In step F112, the CPU 31 replaces the current sub-Q data with the variable SUBLAST, and uses the current sub-Q data as the sub-Q data in the next frame checking process. Thereafter, the flow returns to step F101. In step F101, the CPU 31 repeats the above processes.

If the flow proceeds to step F106, F109 or F117 (in Fig. 6), the CPU 31 performs the process in the retry mode. That is, when the buffer memory 30 becomes full or when the selected quality of data is not satisfied as a result of the frame checking process or the error checking process, the CPU 31 sounds as the retry mode shown in FIG. Perform the connection process. In the sound coupling process, after stopping the temporary writing of data into the buffer memory 30, the CPU 31 restores the writing operation of the data whose continuity is maintained.

In the sound connection process, the CPU 31 jumps the optical head 3 every track so as to retreat the read position on the disc every one peripheral track (in step F201). Thereafter, the CPU 31 checks the space of the buffer memory 30 (in step F202). If the space of the buffer memory 30 is zero, since the reproduced audio signal becomes silent, the flow advances from step F203 to step F204. In step F204, the CPU 31 performs error determination.

If the space of the buffer memory 30 is not zero, the flow advances to step F205. In step F205, the CPU 31 sets the frame check reference value FC corresponding to the space of the buffer memory 30. This process is the same as the process in step F104.

In step F206, the CPU 31 reads the address value as the sub Q data. At this point, the CPU 31 compares the address value with the variable SUBLAST which is the final sub-Q data. The variable SUBLAST is the value of the address of the final data at which the CPU 31 has stopped writing data to the buffer memory 30.

Since the read position is retracted by the one-track jumping operation in step F201, the address read in step F206 depends on the situation at that time.

If the address of the read sub-Q data matches the value of the variable SUBLAST (i.e., the address of the last data stored in the buffer memory 30), the data of the next subcoding frame (address) is the next data. At this point, the flow proceeds from step F207 shown in Fig. 6 to step F110 via the path ①. In step F110, the CPU 31 performs an error checking process on the sound data and stores the result data in the buffer memory 30. That is, the CPU 31 restores the normal playback mode from the retry mode. When the flow advances to step F113 shown in Fig. 6, since the data is read by the retry operation, the CPU 31 sets the error level corresponding to the number of retry operations in step F115.

If the address of the sub-Q data read in step F206 is an address before the address of the variable SUBLAST, the read data does not reach the address of subsequent data to be written to the buffer memory 30. Thus, the flow proceeds to steps F207 and F208 and then returns to step F202. Thus, the CPU 31 continues reading data. Therefore, at a specific timing, the address of the sub Q data read in step F207 coincides with the value of the variable SUBLAST. At this point, flow proceeds to step F110 (in Figure 6). In step F110, the CPU 31 performs an error checking process on the audio data and stores the result data in the buffer memory 30.

If the address of the sub-Q data read in step F206 exceeds the value (address) of variable SUBLAST, the flow advances from step F208 to step F209. In step F209, the CPU 31 determines whether the address is within the frame check reference value FC corresponding to the value of the variable SUBLAST. That is, the CPU 31 determines whether the address is within the allowable range shown in FIG. If the address is within an acceptable range, data drop (eg, 5 frames or less) is allowed. The flow then proceeds to step F110 shown in FIG. In step F110, the CPU 31 checks the error of the Oda data and stores the result data in the buffer memory 30.

If the address of the data read in step F206 significantly exceeds the value of the variable SUBLAST, the CPU 31 determines that the read position is inappropriate. At this point, the flow returns to step F201. In step F20, the CPU 31 retracts the optical head every track. By repeating these processes several times, the CPU 31 causes the read position to be moved to a position before the value of the variable SUBLAST and the reference value FC. That is, in step F207 or F209, there is a possibility that the result determined in step F207 is affirmative.

In the sound connection process, the CPU 31 sets the frame check reference value FC corresponding to the space of the buffer memory 30. Only when the space of the buffer memory 30 is sufficient, the CPU 31 allows dropping of up to five subcoded frames strictly to maintain data continuity. If the space in the buffer memory 30 is insufficient, for example 50% or less, or there is not enough time, the CPU 31 drops the drop of audio data by a certain range, for example, 40 subcoding frames. Allow. Therefore, the situation where the reproduced audio signal is muted can be prevented.

As described above, when data is reproduced by the ESP function, the CPU 31 sets the degree of stringency of the frame checking process corresponding to the space of the buffer memory 30. In addition, the CPU 31 performs an error checking process in response to the number of occurrences of C2PO and changes the degree of stringency of the error checking process in response to the number of spaces and retry operations of the buffer memory 30. Thus, in response to such a situation, the sound state due to the drop of reproduced audio data is not prevented with the highest priority. Data stored in the buffer memory 30 can be maintained in high quality in correspondence with both the frame checking process and the error checking process. Thus, the quality of the reproduced audio can be improved.

According to this embodiment, in addition to the above ESP operation, since the CPU 31 does not make the buffer memory 30 full, there is no possibility that the flow proceeds to step F106 (in Fig. 6). In the retry mode, the number of 1-track jumping operations in step F201 is minimized. That is, unless the result of the frame checking process or the error checking process is smooth, the retry mode is not executed. Thus, the number of 1-track jumping operations is minimized. As a result, the adverse effects of the one-track jumping operation are reduced.

Although the CPU 31 does not make the buffer memory 30 full, it is desirable that the space of the buffer memory 30 be as much as possible in order to achieve the seismic function. That is, in this example, the buffer memory 30 remains almost full, not full. Thus, sufficient seismic function and high quality reproduced audio are achieved.

As described above, the CPU 31 causes the automatic sequencer 23 to be set to the division ratio of the 1 / M divider 22 and the 1 / N divider 24. Therefore, the CPU 31 can control the rotational speed of the spindle motor 2 to any speed. In addition, since the DSP 8 operates in response to the master clock CK following the rotational speed of the spindle motor 2, the DSP 8 can read data regardless of the rotational speed of the spindle motor 2.

On the other hand, when the rotational speed of the spindle motor 2 changes, the read data ratio of the data read from the disk 1 and written to the buffer memory 30 can be changed arbitrarily. Therefore, by adjusting the speed of the spindle motor 2 corresponding to the space of the buffer memory 30, the difference between the write ratio to the buffer memory 30 and the read ratio from the buffer memory 30 is equal to the buffer memory 30. The amount of data stored in it is adjusted to remain near full, but not full.

Next, the process performed by the CPU 31 will be described with reference to FIGS. 10 and 11. 10 is a flowchart showing a control process of the CPU 31 for setting the speed of the spindle motor 2. In step F301, the CPU 31 always checks the amount of data stored in the buffer memory 30. This common process step F101 shown in FIG. 6 and step F202 shown in FIG.

When the space of the buffer memory 30 is 80% or less, this flow proceeds from step F302 to step F304. In step F304, the CPU 31 causes the spindle motor 2 to operate at twice the normal speed.

When the space of the buffer memory 30 is 80% or more and 90% or less, this flow proceeds to steps F302, F303, and F305. Thus, the CPU 31 causes the spindle motor 2 to operate at 1.5 times the normal speed.

When the space of the buffer memory 30 is 90% or more, this flow proceeds to steps F302, F303, and F306. Thus, the CPU 31 causes the spindle motor 2 to operate at 1.5 times the normal speed.

11 is a diagram showing the transition of the amount of data stored in the buffer memory 30 implemented by such processing.

In FIG. 11, the vertical axis represents the space of the buffer memory 30. The horizontal axis represents the time elapsed since the start of the playback operation. When the storage capacity of the buffer memory 30 is 4M bits at 100% on the vertical axis (that is, when the buffer memory 30 is full), the reproduced data is stored for 3 seconds.

When the reproducing operation starts, at the elapsed time of 0 seconds, the amount of data stored in the buffer memory 30 is zero. Thus, in step F304, the CPU 31 causes the spindle motor to be operated at twice the normal speed. The decoded data in the double speed reproducing operation is stored in the buffer memory 30. As indicated by the area A shown in FIG. 11, the amount of data stored in the buffer memory 30 increases.

It is assumed that the amount of data stored in the buffer memory 30 is 50% (data for 1.5 seconds) and the reproduction data is output at 0.75 seconds after the reproduction operation starts. That is, data is read from the buffer memory 30 at a preset rate. This data is output as an audio signal from the terminal 33 via the D / A converter 32.

After 0.75 seconds, data is read from the disk 1 and written to the buffer memory 30 at twice the speed. However, since data is read out from the buffer memory 30 at 1x speed, the increased speed of the stored data is somewhat weakened as indicated in the area B. FIG.

After the data amount is continuously increased as in the area B, when the data amount stored in the buffer memory 30 reaches 80%, this flow proceeds to step F305 (in FIG. 10). Therefore, the CPU 31 switches the speed of the spindle motor 2 to 1.5 times speed. In the 1.5 times playback operation, the decoded data is stored in the buffer memory 30. In this state, the data write rate to the buffer memory 30 decreases. Therefore, as indicated by the area C, the increase rate of the amount of data stored in the buffer memory 30 becomes weaker than in the area B. FIG.

Then, when the amount of data stored in the buffer memory 30 becomes 90% from 2.25 seconds after the reproduction operation starts, the flow proceeds to step F306 (in FIG. 10). Therefore, the CPU 31 switches the speed of the spindle motor 2 to the standard speed (1x speed). The decoded data in the standard speed reproducing operation is stored in the buffer memory 30. In this state, the data write rate to the buffer memory 30 coincides with the data read rate from the buffer memory 30. Thus, as indicated by the area D, the amount of data stored in the buffer memory 30 still remains 90%.

When the retry mode is performed, if the retry mode is performed as a result of the frame checking process and the error checking process, since the data writing operation to the buffer memory 30 is temporarily stopped, the buffer memory 30 is stopped. The amount of data stored therein is reduced. However, the amount of data stored in the buffer memory 30 decreases from 80% to 90% by the processing shown in Fig. 10, and the CPU 31 switches the speed of the spindle motor 2 to 1.5 times speed. When the amount of data stored in the buffer memory 30 decreases to 80% or less, the CPU 31 switches the speed of the spindle motor 2 to double speed. Therefore, the amount of data stored in the buffer memory 30 is restored at 90%. In this state, the speed of the spindle motor 2 is 1x speed. Therefore, the state where the amount of data stored in the buffer memory 30 is 90% is maintained.

As described above, in correspondence with the amount of data stored in the buffer memory 30, the CPU 31 changes the speed of writing the data into the buffer memory to switch the speed of the spindle motor 2. Therefore, the CPU 31 controls the amount of data stored in the buffer memory 30 so that the amount of data stored in the buffer memory 30 is kept almost full (90%). Therefore, in the normal state, the retry operation due to the full state of the buffer memory 30 does not occur. As a result, the number of track jumping operations is the minimum number necessary to maintain data quality. Thus, power consumption due to track jumping operation is reduced. In addition, the degradation of sound quality due to electrical noise in the track jumping operation can be minimized.

Of course, since the data amount of 90% is maintained, the seismic function can be sufficiently implemented.

In addition, the rotational speed of the spindle motor 2 is maintained at almost the standard speed. Thus, the power consumption of the spindle motor 2 can be reduced. In addition, it is not necessary to use a motor that can always rotate at twice the speed as the spindle motor 2. Thus, the cost of the parts can be reduced.

In such a CD player, jitter may be generated in the reproduced signal due to deformation of the disc 1, its displacement, irregular rotation of the drive unit, and the like. When the reproduced signal contains such jitter, the S / N ratio is lowered. Therefore, an error often occurs in the reproduced data. When the rotation speed of the disk 1 is increased, the frequency component of jitter occurs in the high frequency region. When the frequency rises, the S / N ratio of the RF amplifier 7 decreases. Therefore, when the rotation speed of the disk 1 increases and the frequency component of jitter exists in the high frequency region, the S / N ratio is remarkably lowered, thereby lowering the error rate of reproduced data.

As described above, in the seismic processing, the reproduced data is stored in the buffer memory 30. The continuity of the data is determined by the sub Q data. Although the CIRC error correction code is added to the audio data, only the CRC code for detecting the error is added to the sub Q data. Therefore, if the number of revolutions of the disk 1 increases when the jitter component is large, the sub-Q data can be read because the error rate is lowered.

In order to solve such a problem, in this embodiment, jitter is measured. The maximum rotational speed of the disc 1 is determined corresponding to the measured jitter value. In other words, when the jitter is smaller than the reference value, the maximum rotation speed of the spindle motor 2 increases. When this jitter is larger than the reference value, the maximum rotation speed of the spindle motor 2 decreases. Thus, the maximum rotational speed of the disc 1 is set so that its error rate can be tolerated.

Jitter appears as a blur of the RF signal (eye pattern) read from the disc 1. When the RF signal is the same waveform as the EFM signal, which is a binary pulse train, jitter appears as a deflection of the phase of the EFM signal. Therefore, when the difference between the phase of the EFM signal and the phase of the reproduction clock is measured, the intensity of jitter can be obtained.

12 is a block diagram illustrating an example of a jitter detection circuit structure for measuring jitter. In FIG. 12, the EFM signal and the reproduction clock PLCK are supplied to the phase comparator 50. The regenerated clock PLCK is received from the voltage controlled oscillator (VCO) 52. The phase comparator 50 compares the phase of the EFM signal with the phase of the output signal of the VCO 52. The output signal of the phase comparator 50 is supplied to the VCO 52 through the low pass filter 51. The oscillation frequency of the VCO 52 is controlled in response to the output signal of the phase comparator 50 through the low pass filter 51. By such a PLL, the reproduction clock PLCK is extracted.

In addition, the output signal of the phase comparator 50 is supplied to the A / D converter 53. As described above, the jitter intensity is detected corresponding to the difference between the phase of the EFM signal and the phase of the reproduction clock. Thus, the output signal of the phase comparator 50 corresponds to the jitter intensity. The A / D converter 53 digitizes the output signal of the phase comparator 50. The output signal of the A / D converter 53 is supplied to the jitter measuring circuit 54. The output signal of the jitter measurement circuit 54 is supplied to the comparator 55.

The jitter measurement circuit 54 stores, for example, eight frames of the output signal of the A / D converter 53 at one time. Each time the jitter measurement circuit 54 stores 8 frames of signals, the jitter measurement circuit 54 sends a signal to the comparator 55. The comparator 55 compares the signal value described above with a preset value to determine whether the intensity of the jitter exceeds the preset value.

Since one frame of data corresponds to six samples sampled at 44.1 kHz (ie, 136 ms), 8 frames correspond to almost 1 ms. In this embodiment, the reference value of the comparator 55 is designated as a value corresponding to 10 Hz. Thus, the comparator 55 determines whether jitter contained in the RF signal is 10 Hz for the data on the order.

When the signal A is supplied directly to the A / D converter 53, if the influence of the high frequency component is too strong, the output signal of the phase comparator 50 is passed through the low pass filter at a preset cutoff frequency. It can be supplied to the D converter 53. Instead of using the A / D converter 53, the intensity of the jitter can be measured in the following manner. In this case, the output signal of the phase comparator 53 is stored in the capacitor for a preset time period. The voltage is compared with the reference voltage. Alternatively, a jitter detection unit such as that disclosed in Japanese Patent Publication No. 4-63580 can be used.

13 is a flowchart showing a process for determining the maximum rotational speed of a disc corresponding to the measured jitter intensity.

First, in step F401, the disk 1 is chucked. Thereafter, the disk 1 is set in the spindle motor 2. This flow then proceeds to step F402. In step F402, the spindle motor 2 is started. This flow then proceeds to step F403. In step F403, the servo gains of the focus servo motor and tracking servo motor are set to initial values. Thereafter, the servo motors are operated. At this time, the disc 1 is controlled in a constant flux mode. Next, this flow proceeds to step F404. In step F404, each system unit is automatically adjusted. In step F405, the intensity of jitter is measured.

At this time, the intensity of jitter is measured, for example, in the lead-in area of the innermost circumference of the disc 1. This is because the lead-in area on the innermost circumference of the disc 1 has a TOC. In addition, the information of the TOC must be read first. In addition, since the rotational speed is high on the innermost circumference of the disc 1, jitter is likely to occur.

After the intensity of the jitter is measured at step F405, the flow proceeds to step F406. In step F406, it is determined whether the intensity of the jitter is larger than a preset value (for example, 10 mu s).

If the measured jitter intensity is greater than the preset value, the flow proceeds to step F407. In step F407, the maximum rotation speed of the disk 1 is set to 1.5 times speed. If the measured jitter intensity is less than the preset value, the flow proceeds to step F408. In step F408, the maximum rotational speed of the disk 1 is set to 2.0 times speed.

After the maximum rotational speed of the disc is set in steps 407 and F408, this flow proceeds to step 409. In step F409, the speed mode is switched to the variable speed mode. In step F410, TOC data is read from the lead-in area of the disc. In step F411, a reproducing operation for data is started.

In the above-described embodiment, after the disk 1 is chucked, the intensity of jitter is measured once to determine the maximum rotational speed of the disk 1. However, it is desirable to always monitor the jitter intensity because the jitter intensity varies with disk contamination, scratches, and physical defects. In the following embodiment, the intensity of jitter is measured while data is reproduced at a predetermined time interval or at a predetermined number of track intervals. Corresponding to the measured result, the maximum rotation speed of the disc is set.

14 shows that the disc 1 is chucked until data is first reproduced. In this case, the processes shown in FIG. 14 are basically the same as the processes shown in FIG. However, in FIG. 14, the preset value used to measure the intensity of jitter is set corresponding to the jitter intensity table data shown in FIG.

In step F501, the disk 1 is chucked. The disk 1 is set in the spindle motor 2. After the disc 1 is set, this flow proceeds to step F502. In step F502, the spindle motor 2 is driven. This flow then proceeds to step F503. The servo gain and the like of the focus servo motor and tracking servo motor are set to initial values. Thereafter, these servo motors are driven to initial values. At this time, the disc 1 is controlled in a constant flux mode. Next, this flow proceeds to step F504. In step F504, the adjustment values of the individual parts of the system are automatically adjusted. In step F505, the intensity of the jitter is measured. The intensity of jitter is first measured on the innermost circumference of the disk 1, for example.

After the intensity of the jitter is measured in step F505, the flow proceeds to step F506.

In step F506, it is determined whether the measured jitter intensity is greater than a predetermined value. At this time, the selected value is obtained according to the jitter intensity table data shown in FIG. For example, when the 1-time speed CLV mode is used, the predetermined value compared to the intensity of jitter is set to A.

When the measured jitter intensity is greater than the predetermined value, the flow proceeds to step F507. In step F507, the maximum rotational speed of the disc is 1.5 times the speed. If the measured jitter intensity is less than the predetermined value, the flow advances to F508. In step F508, the maximum rotational speed of the disc is set at 2.0 times speed.

After the maximum speed of the disc is set in step F507 or F508, the flow advances to F509. In step F509, the mode is switched to the variable speed mode. Thereafter, the flow advances to F511. In step F511, a data reproducing operation is started.

Figure 16 shows a process for measuring the intensity of jitter at intervals of a predetermined period. In step F601, it is determined whether the selected period has elapsed. If the selected period has elapsed, the flow advances to F602. In step F602 the speed of the disc is set to the maximum rotational speed. The predetermined value compared with the intensity of the jitter is obtained according to the jitter intensity table data shown in FIG. 15 (F604).

In step F605, the intensity of jitter is measured. It is determined whether the intensity of the jitter measured in step F606 is greater than the predetermined value.

If the measured intensity of jitter is greater than the predetermined value, the flow proceeds to step f607. In step F607 the maximum rotational speed of the disc is set to 1.5 times the speed. If the intensity of the jitter measured is less than the predetermined value, the flow advances to step F608. In step F608, the maximum rotation speed of the disc is set at 2.0 times speed.

Alternatively, the intensity of jitter may be measured in intervals of a predetermined number of tracks instead of intervals of predetermined periods. 17 shows a process for measuring the intensity of jitter at intervals of a predetermined number of tracks. In step F701, it is determined whether the selected number of tracks have passed. When the predetermined number of tracks have passed, the flow advances to step F702. In step F702, the speed of the disc is set to the maximum speed. In step F705, the predetermined value compared to the intensity of jitter is obtained from the jitter intensity table shown in Fig. 15 corresponding to the current rotational speed of the disc (step F703).

In step F705, the jitter intensity is measured. In step F706, it is determined whether the measured jitter intensity is greater than a predetermined value.

When the measured jitter intensity is greater than the predetermined value, the flow advances to F707. In step F707 the maximum rotational speed of the disc is set to 1.5 times the speed. If the measured jitter intensity is less than the predetermined value, the flow proceeds to step F708. In step F708 the maximum rotation speed of the disc is set at 2.0 times speed.

While the data is being reproduced, if a track jumping operation is performed, a process as shown in FIG. 18 is executed. When the track jumping operation is executed in step F801, the floe proceeds to step F802. In step F802, the current track is accessed. Thereafter, the flow advances to step F803. In step F803, the maximum rotational speed of the disc is set at 1.5 times speed. Thereafter, the flow advances to step F804. In step F804, a data reproducing operation is started.

In the above-described embodiments, a reproduction device of a variable speed control type (i.e., a wide capture type) has been described. It should be noted, however, that the present invention is not limited to such embodiments. Instead, you can switch the system clock to increase or decrease the rotational speed of the disk. Alternatively, the CPU can switch the rotation speed of the disk between standard speed and double speed.

Although specific preferred embodiments of the present invention have been described with reference to the accompanying drawings, the present invention is not limited to these embodiments, and those skilled in the art will recognize the spirit and scope of the present invention as defined in the appended claims. It should be understood that various modifications and changes can be made to the present invention without departing from the scope.

According to the invention, the maximum speed of the spindle motor is set according to the jitter strength of the disk from which the data of the disk from which data is read is read. Thus, while the data is being reproduced, the zeta strength is measured at intervals of a predetermined period or at a predetermined number of track intervals to set the maximum speed of the spindle motor. Thus, data can always be read at the highest speed available unless a data error occurs.

Claims (9)

In the information reproducing apparatus, Reproducing means for reproducing information read by the reading means from the recording medium; Driving means for driving a recording medium with respect to said reading means; Measuring means for measuring jitter of information reproduced by the reproducing means; Storage means for temporarily storing the information recorded on the recording medium at a first transfer rate; Reading means for reading information recorded on the recording medium at a second transfer rate lower than the first transfer rate; And And drive control means for controlling the speed of the drive means in accordance with the jitter measured by the measurement means. An information reproducing apparatus according to claim 1, wherein the maximum speed of said driving means is set in accordance with the jitter value measured by said measuring means. 2. The apparatus according to claim 1, wherein said measuring means comprises phase comparison means for detecting a difference between a phase of an EFM signal reproduced from said recording medium and a phase of a reproduction clock signal to determine jitter corresponding to an output signal of said phase comparison means. Information playback device to measure. 3. The apparatus of claim 2, wherein the drive control means controls the drive means in a constant linear velocity mode while the measurement means measures the jitter component; And the drive control means controls the drive means in a variable speed mode after the maximum speed is set. In the information reproducing apparatus, Reproducing means for reproducing information read by the reading means from the recording medium; Driving means for driving a recording medium with respect to said reading means; Measuring means for measuring jitter of information reproduced by the reproducing means; Storage means for temporarily storing the information recorded on the recording medium at a first transfer rate; Reading means for reading information recorded on the recording medium at a second transfer rate lower than the first transfer rate; And And drive control means for causing the measurement means to measure jitter a plurality of times while the reproduction means is reproducing the recording medium and to control the speed of the drive means in accordance with the measured jitter. 6. An information reproducing apparatus according to claim 5, wherein said measuring means first measures jitter on the innermost periphery of said recording medium. An information reproducing apparatus according to claim 5, wherein the maximum speed of said driving means is set in accordance with the value of jitter measured by said measuring means. 6. The apparatus according to claim 5, wherein said measuring means comprises phase comparison means for detecting a difference between a phase of an EFM signal reproduced from said recording medium and a phase of a reproduction clock signal to obtain jitter corresponding to the output signal of said phase comparison means. Information playback device to measure. 7. The apparatus of claim 6, wherein the drive control means controls the drive means in a constant linear velocity mode while the measurement means is measuring the jitter component; And the drive control means controls the drive means in a variable speed mode after the maximum speed is set.