JP3687066B2 - Rotating motor control device for recordable optical disk device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical disc device that drives a recordable optical disc (hereinafter referred to as a recordable optical disc device), and more particularly to a control circuit and an LSI in a rotary motor control device of a recordable optical disc device.
[0002]
[Prior art]
An optical disk is used as a device for recording a large amount of information.
Here, an outline of the optical disc and the drive configuration will be described.
Common CD-R and CD-E discs are writable (recordable) CDs (compact discs).
The former CD-R (CD recordable) is a CD that can be written only once (also referred to as CD-Write Once).
The latter CD-E (CD erasable) is a CD that can be written a plurality of times (note that CD-RW is also called CD rewritable).
Information is recorded and reproduced on these CD-R and CD-E discs, that is, optical discs, by a drive as shown in FIG.
[0003]
FIG. 25 is a functional block diagram showing an example of a main part configuration of an optical disk drive. In the figure, 1 is an optical disk, 2 is a spindle motor, 3 is an optical pickup, 4 is a motor driver, 5 is a read amplifier, 6 is a servo means, 7 is a CD decoder, 8 is an ATIP decoder, 9 is a laser controller, and 10 is a CD. Encoder, 11 CD-ROM encoder, 12 Buffer RAM, 13 Buffer manager, 14 CD-ROM decoder, 15 API / SCSI interface, 16 D / A converter, 17 ROM, 18 CPU, 19 RAM indicates LB, laser light, and Audio indicates an audio output signal.
[0004]
In FIG. 25, the arrow indicates the direction in which data mainly flows. In order to simplify the drawing, the CPU 18 that controls each block in FIG. Is omitted.
The configuration and operation of the optical disk drive are as follows.
The optical disk 1 is rotationally driven by a spindle motor 2. The spindle motor 2 is controlled by the motor driver 4 and the servo means 5 so that the linear velocity is constant. This linear velocity can be changed stepwise.
[0005]
The optical pickup 3 includes a semiconductor laser, an optical system, a focus actuator, a track actuator, a light receiving element, and a position sensor (not shown), and irradiates the optical disc 1 with the laser beam LB.
The optical pickup 3 can be moved in the sledge direction by a seek motor.
These focus actuator, track actuator, and seek motor are positioned at a target location on the optical disc 1 by the motor driver 4 and the servo means 5 based on signals obtained from the light receiving element and the position sensor. To be controlled.
[0006]
At the time of reading, the reproduction signal obtained by the optical pickup 3 is amplified by the read amplifier 5 and binarized, and then input to the CD decoder 7.
The input binarized data is demodulated by the CD decoder 7 with EFM (Eight to Fourteen Modulation).
Note that the recording data is EFM modulated by collecting 8 bits at a time. In this EFM modulation, 8 bits are converted to 14 bits, and 3 bits are added to form a combined bit to make a total of 17 bits.
In this case, the combined bits are attached so that the number of previous “1” s and “0” s are equal on average. This is called “DC component suppression”, and the slice level fluctuation of the DC-cut reproduction signal is suppressed.
[0007]
The demodulated data is subjected to deinterleaving and error correction.
Thereafter, this data is input to the CD-ROM decoder 14, and further error correction processing is performed in order to improve the reliability of the data.
The data that has been subjected to the error correction processing twice as described above is temporarily stored in the buffer RAM 12 by the buffer manager 13 and is arranged as sector data to the host computer (not shown) via the ATAPI / SCSI interface 15. It is transferred at a stretch.
In the case of music data, the data output from the CD decoder 7 is input to the D / A converter 16 and extracted as an analog audio output signal Audio.
[0008]
At the time of writing, data sent from the host computer through the ATAPI / SCSI interface 15 is temporarily stored in the buffer RAM 12 by the buffer manager 13.
The write operation is started in a state where a certain amount of data is accumulated in the buffer RAM 12. In this case, it is necessary to position the laser spot at the write start point before that.
This point is obtained by a wobble signal preliminarily carved on the optical disc 1 by meandering tracks.
[0009]
The wobble signal includes absolute time information called ATIP, and this information is extracted by the ATIP decoder 8.
The synchronization signal generated by the ATIP decoder 8 is input to the CD encoder 10 so that data can be written at an accurate position on the optical disc 1.
Data in the buffer RAM 12 is added to the error correction code and interleaved by the CD-ROM encoder 11 and the CD encoder 10, and is recorded on the optical disk 1 via the laser controller 9 and the optical pickup 3.
[0010]
The EFM modulated data drives the laser as a bit stream at a channel bit rate of 4.3218 Mbps (standard speed).
The recording data in this case constitutes an EFM frame in units of 588 channel bits.
The channel clock means a clock having a frequency of this channel bit.
The above is the outline of the configuration and operation of the optical disk drive of FIG.
[0011]
By the way, in MD (mini-disc), CD-R (CD recordable: compact disc that can be written once), CD-E (CD erasable: compact disc that can be erased and written multiple times). Is engraved with a spiral guide groove.
The guide groove has a very small amount (in the radial direction of the disk) at a constant spatial frequency (for example, 17,000 cycle / m: 59 μm per cycle) so that rotation control of CLV (Constant Linear Velocity) is possible. (For example, about 0.03 μm) meandering.
The drive device can rotate the disk at a constant (for example, 1.3 m / s) linear velocity by driving the rotary motor so that the meandering signal frequency is constant (for example, 22.05 KHz).
Thus, the guide groove is meandering, and a disc device that detects the meandering frequency and controls the rotation of the disc is conventionally known (for example, JP-A-6-338066).
[0012]
Further, address information is superimposed on the meandering signal frequency by FM (frequency modulation).
For example, information “1” is modulated to 23.05 KHz, and information “0” is modulated to 20.05 KHz.
Since the numbers of the information “1” and “0” are the same on average, the CLV control is actually set so that the mean frequency of the meandering signal is 22.05 KHz. ing.
[0013]
The address information is called ATIP (Absolute Time In Pre-groove).
The meandering signal is called a wobble signal. This wobble signal is an ATIP carrier signal.
There is also known an apparatus that performs CLV control by controlling rotation so that the carrier wave of the meandering groove becomes constant, and obtains an address signal by the carrier wave modulation component of the meandering groove (for example, Japanese Patent Laid-Open No. 5-225580). .
[0014]
Further, a one-chip LSI used in such an optical disk drive, for example, a CD-R drive, is already on the market (for example, LC89590 manufactured by Sanyo Electric Co., Ltd. and its explanation and application data).
As described above, as a conventional technique, a circuit that performs CLV control in synchronization with a wobble signal and a circuit that performs CLV control in synchronization with an ATIP address synchronization signal (ATIPSYNC) are well known.
However, these prior arts do not disclose the relationship between the rotation control circuit for reproducing the reproduction signal disk and the rotation control circuit for rotating the recording disk.
There is also no disclosure regarding rotation control in a data area partially recorded on a recording disk.
[0015]
[Problems to be solved by the invention]
As previously described in the prior art, a circuit that performs CLV control in synchronization with a wobble signal and a circuit that performs CLV control in synchronization with an ATIP address synchronization signal (ATIPSYNC) are well known.
However, in the area where the data is recorded on the recording disk, the wobble signal is disturbed by the recorded data and may not be detected accurately. If the rotation control by the wobble signal is continued continuously, the wobble signal is unstable. There is a problem that it is easy to become.
In order to improve the S / N ratio, the wobble signal must generally be detected through a narrow-band bandpass filter (BPF), but has reached the target linear velocity at the time of access or at the start of rotation. When there is not, the wobble signal cannot be accurately detected because it is shifted from the pass band of the band pass filter.
Therefore, even in such a case, there arises a problem that rotation control tends to become unstable.
[0016]
Furthermore, it is also known to set a mode for controlling rotation in synchronization with the address synchronization signal (ATIPSYNC) (explanation of LC89590 made by Sanyo Electric Co., Ltd. and application data).
This mode is added because the control of the wobble signal cannot be completely synchronized with the address information due to bit slip or the like.
However, since the address synchronization signal (ATIPSYNC) has a low frequency of 75 Hz, the rotation control cannot be performed in a high band, and it is difficult to perform precise control.
[0017]
In addition, in the control as described above, switching between the playback disk control mode, the control mode by the wobble signal, the control mode by the address synchronization signal (ATIPSYNC), etc. is generally performed by a command from a CPU (microcomputer) or Since it must be performed by an external circuit, there are many problems such as difficulty in programming and cost increase due to the external circuit.
An object of the present invention is to realize an optical disk rotation motor control device capable of always performing stable and precise rotation control by effectively and automatically switching these many modes.
It is another object of the present invention to provide a motor control device that is low in cost and has little programming burden.
[0018]
[Means for Solving the Problems]
According to the first aspect of the present invention, there is provided a rotation motor control device for a recordable optical disk apparatus, and a meandering synchronous rotation control circuit for controlling rotation of the rotation motor based on a meander signal generated corresponding to the meandering of the guide groove of the disk. A synchronization signal detection circuit for detecting an address synchronization signal arranged as meandering of the guide groove at a predetermined distance in a line direction of the guide groove, and a phase for comparing phases of the address synchronization signal and the reference clock signal An address-synchronized rotation control circuit having a comparator and a variable frequency oscillator that outputs a reference signal having a frequency corresponding to the comparison result of the phase comparator, and supplying the reference signal to the meandering synchronous rotation control circuit The meandering synchronous rotation control circuit controls the rotary motor based on the meandering signal until a predetermined position before the recording start address, It is subjected during the recording operation from the front only position, so as to control the rotary motor on the basis of the meandering signal and the reference signal.
[0021]
According to a second aspect of the present invention, there is provided a recordable optical disk device comprising the rotary motor control device according to the first aspect, wherein the data synchronous rotation control circuit performs rotation control of the rotary motor in synchronization with the recorded data signal; The first digital signal processing LSI includes a phase synchronization circuit that is phase-synchronized with the data signal, and a synchronization detection circuit that detects that the phase synchronization circuit is in a synchronized state and outputs a lock signal. This processing means is built in the second digital signal processing LSI.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
First, a 1-chip LSI in which the rotation motor control device of the recordable optical disk device of the present invention is housed, that is, a 1-chip LSI in which functions for a drive device of a CD-R disk that is a recordable optical disk are integrated. Will be described.
[0023]
2 and 3 are functional block diagrams showing an example of the configuration of the main part of a one-chip LSI in which functions for a CD-R disk drive device are integrated. The reference numerals in the figure are the same as those in FIG. 25, the same reference numerals are added to the interface, 20 is a rotary motor controller, 21 is a clock generator, 22 is a clock synthesizer, 23 is a CIRC encoder, and 24 is a subcode operator. 25 indicates a sector processor, 26a indicates a CD-DA interface, 27a indicates a RAM interface, and 28a indicates a DRAM interface.
[0024]
The one-chip LSI having the function for the CD-R disk drive device shown in FIGS. 2 and 3 mainly includes the EFM encoding function and the CD-ROM among the functional blocks of the optical disk drive shown in FIG. The encoding / decoding function block and the block relating to the rotary motor control device 20 that controls the driving of the motor driver 4 are integrated into an LSI.
The overall configuration and the basic operation principle are the same as those of the conventional blocks. However, as described in the first to fourteenth embodiments, a rotary motor that controls the driving of the motor driver 4 is described below. The control device 20 has a feature.
[0025]
Here, an overall description will be given of a one-chip LSI including the rotary motor control device of the present invention.
2 and 3, the subcode interface 24a, the CD-DA interface 26a, the CD encoder 10, the buffer manager 13, the sector processor 25, the DRAM interface 28a, the ATAPI interface 15a, and the system controller interface 18a are read / write data. A processing circuit is configured.
The system controller interface 18a incorporates a register group for writing commands to the one-chip LSI from the CPU 18 shown in FIG. 25 and reading the internal state of the one-chip LSI.
The rotary motor control device of the present invention is integrated in the rotary motor control device 20 shown below in the block of FIG.
The related pin assignments (motor control interface signals) are detailed in the following FIG.
[0026]
FIG. 4 is a diagram showing interface signals in the rotary motor control device 20 shown in FIG.
[0027]
The REVDET signal is a signal indicating that the motor has reversed.
The DPLOCK signal is a signal indicating the locked state of the PLL of the CD-DSP (CD digital signal processing circuit).
The FGIN signal is a signal having a frequency proportional to the rotational speed of the motor.
The TON signal is a signal indicating that the light beam is tracking the track of the disk.
The MPWM signal is a motor control output signal, and MPWMP and MPWMN are positive and negative signals.
[0028]
The DMCON signal is a CD-DSP servo switching signal of the one-chip LSI shown in FIGS.
The MON signal is an ON signal for the motor driver.
The SBRK signal is a signal for applying a brake to the motor by shorting the coil of the motor.
By the way, the command and status registers related to the rotary motor control device 20 will be described with reference to FIGS. 5 to 8 below. However, the required number of registers having an 8-bit configuration is provided (for example, 13 in total). Yes.
Among them, the servo control register described in the embodiment particularly has addresses 0x80 to 0x84 (0x indicates the meaning of hexadecimal notation).
[0029]
FIG. 5 is a diagram illustrating an example of the TON signal and the DPLMSK signal register.
[0030]
First, the TON signal register is stored in bit 7 at its address 0x80.
The bit 7 is set to “1” when the tracking servo is on, and “0” when it is off.
For example, automatic switching in the FG / DEC or FD / WBL auto mode, which will be described later, is performed by turning on / off the tracking servo.
When the tracking servo is turned on, the ATIP decoding forcible search starts, and the timing of the CD encoder is initialized when synchronization is detected.
[0031]
The DPLMSK signal register is then stored in bit 2 at the same address 0x80.
This DPLMSK signal is a bit for setting whether or not to insert a DPLOCK signal as a switching determination condition in the auto mode.
When this bit is set to “1”, the DPLOCK signal is set not to enter in the switching judgment condition in the auto mode, and it becomes effective in the auto mode including the DEC mode (FG / DEC mode or FG / WBL / DEC mode). Only the TON signal is set as the switching condition.
When this bit is set to “0”, the DPLOCK signal is used as a determination condition.
[0032]
FIG. 6 is a diagram showing an example of the SVMODE signal register. (1) shows the spindle servo mode, (2) shows the manual mode, and (3) shows the auto mode.
[0033]
As shown in FIG. 6A, the SVMODE signal register has bits 0 to 81 at the address 0x81.
The details are shown in FIG. 6 (2) for the manual mode and in FIG. 6 (3) for the auto mode.
In the case of the auto mode, as shown in FIG. 6 (3), eight modes can be set. Here, a case where six modes are set is shown.
When the contents set in bits 7 to 4 in the SVMODE signal register are “1000”, automatic switching from the kick mode to the FG mode is performed.
When the setting is “1001”, automatic switching from the brake mode to the stop mode is performed.
Other modes are also set, but will be described in detail in each embodiment.
[0034]
FIG. 7 is a diagram illustrating an example of the KICDAT signal register.
[0035]
The register of the KICDAT signal is stored in bits 7 to 0 at the address 0x82.
The register of the KICDAT signal is a register for setting kick data in the kick mode and the brake mode.
[0036]
FIG. 8 is a diagram showing an example of the FGMTH signal and the FGMTL signal register, where (1) shows the FGMTH signal register and (2) shows the FGMTL signal register.
[0037]
As shown in FIG. 8A, the FGMTH signal register shows a case where bits 4 to 0 are set.
The FGMTL signal register is shown in FIG.
Detailed description will be given in the embodiment described later.
As shown in FIGS. 5 to 8 described above, each of the bits 7 to 0 can be set for the command and status register relating to the rotary motor control device 20 provided in the one-chip LSI of FIG.
Next, an outline of the hardware configuration and functions of the rotation motor control device for the optical disk of the present invention will be described.
[0038]
FIG. 1 is a functional block diagram showing an example of an embodiment of the configuration of the main part of a rotary motor control device for an optical disk according to the present invention. The reference numerals in the figure are the same as those in FIGS. 2 and 3, 31 is a motor control circuit, 32 is a CD-DSP LSI, 32a is a decode PLL, 32b is a frequency control unit, 32c is an EFM synchronization lock unit, and 32d is a CLV control unit. , 33 is a motor driver, 34 is a filter, 35 is a switch, 36 is a midway switch, C is a capacitor, and R and R1 are resistors.
[0039]
The CD-DSP LSI 32 at the upper left in FIG. 1 has a function of inputting data EFM from the disc and decoding the data when reproducing the recorded portion of the reproduced CD and recordable CD. Hereinafter, the CD-DSP LSI 32 is abbreviated as a CD-DSP from the viewpoint of emphasizing its function.
This CD-DSP also has a CLV control function that keeps the linear velocity of the disk constant.
This CLV control function is realized by comparing the phase and frequency of the clock output from the PLL (decode PLL) circuit that is phase-synchronized with the reproduction data signal EFM and the reference frequency signal, and driving the rotary motor based on the result. .
Alternatively, the rotary motor may be driven so that the period of the specific synchronization pattern included in the reproduction data signal EFM matches the period of the reference frequency.
Furthermore, the motor is driven so that the maximum inversion interval matches the cycle of the reference frequency by utilizing the fact that the maximum inversion interval of the reproduction data signal EFM has a certain period (11T: about 2.5 μs at the standard speed). May be.
In short, any configuration that controls the rotary motor in synchronization with the data signal recorded on the disk is sufficient.
Such a CD-DSP LSI 32 is already on the market, and this LSI can be obtained.
[0040]
In FIG. 1, the rotary motor drive output by the CD-DSP is output from the CLV control unit 32 d that is the “CLV” block and input to the motor driver 33.
There are a switch 36 and a resistor R / capacitor C on the way. Generally, the resistor R / capacitor C is a digital signal in which the output from the CD-DSP is modulated by PWM (Pulse Width Modulation). This signal is added to be converted into an analog signal by a low-pass filter composed of a resistor R and a capacitor C.
[0041]
The midway switch 36 is ON / OFF controlled by a DMCON (Decoder Motor Control ON) signal from the motor control circuit 31.
When this switch 36 is on, the motor driver 33 is driven by the CLV output of the CD-DSP, and when it is off, the motor driver 33 is driven by the motor control output MPWM.
In this case, when the switch 36 is turned on halfway, the motor control output MPWM is set to high impedance so that it does not collide with the control output of the CD-DSP.
[0042]
From the CD-DSP, a DPLOCK (Decoder PLL Lock) signal indicating that the PLL synchronized with the data EFM signal is locked is output, and this signal is input to the motor control circuit 31.
In the motor control circuit 31, the motor control mode is switched by this DPLOCK signal.
The DPLOCK signal is designed to be active when, for example, the synchronization pattern included in the data EFM can be continuously detected.
The SBRK signal is a signal for applying a brake to the motor by short-circuiting the motor coil, and is input to the motor driver 33.
The FGIN signal is a signal having a frequency proportional to the rotational speed of the motor, and is generally output from the motor driver 33.
The REVDET signal is a signal indicating that the motor has been reversed, and this signal is also generally output from the motor driver 33.
[0043]
By the way, generally, in a CD-ROM or CD-R device, a three-phase brushless motor is used as a rotary motor.
In this three-phase brushless motor, the drive coils have three phases, and rotational torque is generated by sequentially passing a three-phase current through these coils.
In order to switch the current, the rotation angle of the motor is detected by a Hall element or the like, and a signal having a frequency proportional to the rotation speed of the motor is obtained from the Hall element or the like.
This signal is called an FG (Frequency Generator) signal, and a signal to which this FG signal is input is FGIN. As this FGIN signal, a signal obtained by shaping the waveform of the FG signal with a driver IC is generally used.
Further, when all the three-phase coil ends of the motor are connected (short-circuited), the motor tries to stop. This is a short brake.
Further, two or three Hall elements are generally attached, and the rotation direction is detected by the phase relationship of the outputs.
A signal using this is REVDET.
Other signals are not directly related to the rotary motor control device of the present invention, and thus the description thereof is omitted.
[0044]
The above is the outline of the configuration and functions of the rotation motor control device 31 for the optical disk of the present invention shown in FIG.
Next, control modes that can be set in the rotary motor control device 31 of the present invention will be described.
The servo mode of the spindle motor is set by the SVMODE signal register shown in FIG. That is, bits 7 to 4 of the address 0x81 are set.
[0045]
FIG. 9 is a diagram illustrating an example of setting of the manual mode for the servo mode of the spindle motor.
[0046]
As shown in FIG. 9, eight types of manual mode can be set. In the motor stop mode STOP, DMCON = L (switch off) and MPWM = Z (high impedance), and the motor is not driven.
In the kick acceleration mode KICK, the motor is accelerated with a predetermined power. The predetermined power in this case can be specified by the register 0x82 (KICDAT in FIG. 7). In the brake mode BRAKE, the motor is decelerated with a predetermined power. The predetermined power in this case is also set by the register 0x82 (KICDAT in FIG. 7).
In the FG mode, the motor control output signal MPWM is output according to the difference between the cycle of the FGIN signal and the target cycle by CAV (Constant Angular Velocity) control using the pulse input of the FGIN signal. Control to match the cycle.
[0047]
The WBL mode is a mode in which the rotary motor is rotated in synchronization with a wobble signal that is a meandering signal of the guide groove of the CD-R disc.
The AX mode is a mode in which the rotary motor is rotated in phase with a synchronization signal (ATIP Sync) included in a fixed period in an ATIP signal (address information signal) that is FM-modulated into a wobble signal.
The DEC mode is a mode in which the rotary motor is rotated by the above-described CLV control (control for keeping the linear velocity of the disk constant) of the CD-DSP.
Note that HOLD is a previous value hold, but is not directly related to the rotary motor control device of the present invention, and thus the description thereof is omitted.
The above is the content of the manual mode in the servo mode of the spindle motor.
[0048]
FIG. 10 is a diagram illustrating an example of setting the auto mode for the servo mode of the spindle motor.
[0049]
KICK to FG is a mode that automatically switches from the kick acceleration mode KICK to the FG mode.
BRAKE to STOP is a mode in which automatic switching from the brake mode BRAKE to the stop mode STOP is performed.
FG / DEC is a mode for automatically switching between FG / DEC modes, and switching between both modes is performed under certain conditions.
[0050]
FG / WBL is a mode in which automatic switching between FG / WBL modes is performed, and switching between both modes is executed under certain conditions.
FG / WBL / DEC is a mode for automatically switching between FG / WBL / DEC modes).
WBL / AX is a mode in which automatic switching between WBL / AX modes is performed, and switching between both modes is performed under certain conditions.
These servo modes can be set manually by the CPU, and the motor rotation can be controlled in each mode. In the present invention, these modes can be switched in the automatic mode. Therefore, it is characterized in that the programming is simplified and the stability of the control operation is improved.
[0051]
First Embodiment In the first embodiment, the DEC mode and the WBL mode (exactly speaking, as shown in FIG. 10 above) among the FG / DEC / WBL modes shown in FIG. Are all in auto mode, but are abbreviated as mode as appropriate).
[0052]
The DEC mode is a mode in which the motor is controlled by the function of the CD-DSP. The MPWM signal that is a motor control output signal and its positive and negative signals MPWMP and MPWMN are set to “1” in the bit 5 of the servo control register shown in FIG. When set to high impedance, when set to “0”, the output of the loop filter becomes a constant PWM signal.
The connection switching control signal DMCOM with the motor driver becomes “H”.
In the WBL mode, the result of adding the speed comparison signal and phase comparison signal of the wobble signal and the encoder EFM frame sync signal (EEFS) is output as a PWM signal.
First, the operation in the FG / DEC / WBL mode when there is recording data will be described.
[0053]
FIG. 11 is a time chart for explaining the operation in the FG / DEC / WBL mode when there is recording data for the rotary motor control device of the present invention. The reference numerals given to the respective waveforms in the figure correspond to the code positions in FIG.
[0054]
In this case, the mode automatic switching operation is in the DEC mode when the DPLOCK signal is active, and in the WBL mode when inactive.
That is, when the decoder PLL of the CD-DSP is in a locked state, stable data synchronization is established, so that the rotary motor control is performed based on the recording data.
When the CD-DSP decoder PLL is not locked, the rotary motor is controlled based on the wobble signal.
Such an operation is effective at the time of controlling rotation of a CD-R or CD-RW (rewritable CD: CD rewritable) in which a recorded portion and an unrecorded portion are mixed.
[0055]
In the recorded portion, the wobble signal is disturbed by the data and the S / N ratio becomes low, so that it is difficult to detect stably.
Therefore, if rotation control is continued with the wobble signal as it is, it becomes unstable due to noise.
In this first embodiment, paying attention to the fact that it is more stable to control based on recorded data (EFM) in such a place, the decoder PLL of the CD-DSP is in a locked state. At times, the rotary motor control is performed based on the recording data.
However, since there is no data (EFM) in the unrecorded portion, it is impossible to control based on the data (EFM).
For this reason, it is necessary to perform rotation control using a wobble signal.
Here, the configuration of the circuit in the WBL mode will be described.
[0056]
FIG. 12 is a functional block diagram showing an example of an embodiment of the main configuration of a circuit in the WBL mode. 1 is the same as FIG. 1, 41 is a debounce circuit, 42 is a wobble PLL, 43 is a speed difference detector, 44 is a phase difference detector, 45 is a PWM output circuit, 46 and 47 are amplifiers, and 48 is an addition. Indicates a vessel.
[0057]
As shown in FIG. 12, in the circuit of the WBL mode, the speed difference detector 43 compares the wobble signal input WBLIN and the encoder EFM frame sync signal EEFS to obtain a speed comparison signal. The encoder EFM frame sync signal EEFS is compared with the phase difference detector 44 to obtain a phase comparison signal.
Then, the speed comparison signal and the phase comparison signal are added by the adder 48, and the addition result is input to the PWM output circuit 45 to generate the MPWM, MPWMP, and MPWMN signals.
Therefore, in the WBL mode, the rotary motor can be rotated in synchronization with the wobble signal that is the meandering signal of the guide groove of the CD-R disc.
[0058]
In order for such a switching operation to be performed by the CPU, the DPLOCK signal must be monitored quite frequently, increasing the burden on the CPU and making it difficult to rotate at high speed.
As a result, it becomes difficult to increase the recording / reproducing speed of the drive device.
On the other hand, in the first embodiment, since the control mode is automatically switched without monitoring by the CPU, the drive apparatus can be speeded up.
[0059]
In this mode, as shown in FIG. 11, both the TON signal indicating that the optical beam is tracking the track of the disk and the DPLOCK signal are active, and a certain time (for example, 256 EFM frame) has passed. Sometimes it is more preferable to configure to shift to the DEC mode for the first time.
Here, the EFM frame is one unit of data on the disc, and is about 136 μs in the case of the standard speed of CD.
By counting time in frames, when controlling at speeds such as 2x, 4x, or 8x faster than the standard speed (1x), the time is automatically set to a short time, making it suitable for speeding up. It is.
[0060]
In addition, by including the TON signal as a condition, it is guaranteed that the track tracking state exists, and when the track tracking state is not transient such as when accessing, the data synchronous rotation control becomes unstable because the data reproduction is not normal. The inconvenience of becoming is avoided.
In the timing chart shown in FIG. 11, in addition to the operation in the FG / WBL mode shown in FIG. 13, the “H” period of the TON signal and the DPLOCK signal is set by a servo gain register (not shown). If it continues beyond the value, it will automatically switch to the DEC mode.
As described above, the first embodiment is control related to automatic switching between the DEC mode and the WBL mode in the FG / DEC / WBL mode.
[0061]
Therefore, a data synchronous rotation control circuit that performs rotation control of the rotary motor in synchronization with the recorded data signal, a meander synchronous rotation control circuit that performs rotation control of the rotary motor in synchronization with the meandering of the guide groove of the disk, A phase synchronization circuit that is phase-synchronized with the data signal and a synchronization detection circuit that detects that the phase synchronization circuit is in synchronization and outputs a lock signal are provided. When the lock signal is obtained, the data synchronization rotation control circuit When the lock motor cannot be obtained, the rotary motor is driven by the meandering synchronous rotation control circuit.
Therefore, the meandering synchronous rotation control mode and the data synchronous rotation control mode are automatically switched without burden on the CPU constituting the controller, and stable control can be performed even if recorded portions and unrecorded portions are mixed. A mode is obtained.
In addition, since there is no burden on the CPU, the firmware code size can be reduced, and cost reduction and high-speed rotation can be easily realized.
In addition to the above conditions, the operation combined with the FG control mode will be described in detail in a seventh embodiment described later.
[0062]
Second Embodiment In the previous first embodiment, control related to automatic switching between the DEC mode and the WBL mode in the FG / DEC / WBL mode has been described.
In the second embodiment, the DPLOCK signal described in the first embodiment is input as a condition for switching to the DEC mode in the FG / DEC mode.
Here, the operation in the FG / DEC auto mode will be described.
[0063]
FIG. 13 is a time chart for explaining the operation in the FG / DEC auto mode for the rotary motor control device of the present invention. The reference numerals given to the respective waveforms in the figure correspond to the code positions in FIG.
[0064]
FIG. 13 shows the operation at the time of track jump.
When the tracking servo is on, automatic switching between the FG mode and the DEC mode is performed based on an input signal indicating the synchronization state of the data EFM obtained from the TON signal and the DPLOCK signal.
As shown in FIG. 13, when the DPLOCK signal is active, CD-DSP control is performed in the DEC mode, and when the DPLOCK signal is inactive, the FG mode is set.
[0065]
When the DPLOCK signal is active, the CD-DSP decoder PLL is locked, and the CLV control can be applied in synchronization with the data EFM.
On the other hand, when the DPLOCK signal is inactive, the data EFM signal is not normal or the linear velocity is not settled to a range where the PLL can be pulled in at the time of access or the like.
Therefore, in this case, FG control is performed as the FG mode.
[0066]
Here, the configuration of the FG mode circuit and the interface circuit of the CD encoder will be described.
[0067]
FIG. 14 is a functional block diagram showing an example of an embodiment of the main configuration of an FG mode circuit. Reference numerals in the figure are the same as those in FIG. 1, 51 is a debounce circuit, 52 is a period detector, 53 is a full acceleration / deceleration pulse generation circuit, 54 is a PWM output circuit, and 55 is a pulse switching circuit.
[0068]
In the FG mode circuit shown in FIG. 14, the period detector 52 detects the difference between the period of the FGIN signal and the target period.
In this case, counting is performed with an encoder EFM frame sync pulse (EEFS).
The full acceleration / deceleration pulse generation circuit 53 generates a pulse obtained by multiplying the difference between the target period and the detection period by a gain.
The PWM output circuit 54 outputs a PWM pulse corresponding to the loop filter data calculation result.
The output terminal outputs the pulse during the output pulse generation period from the full acceleration / deceleration pulse generation part, and outputs the pulse from the PWM pulse output part from the PWM output circuit 54 during the non-generation period.
[0069]
FIG. 15 is a functional block diagram showing an example of an embodiment of the main configuration of an interface circuit of a CD encoder. The reference numerals in the figure are the same as those in FIG. 1, 61 is a counter, 62 is a 1 / N frequency divider, and 63 is a servo decode EFS count register.
[0070]
The interface circuit of the CD encoder shown in FIG. 15 has a function of detecting the disk linear velocity, and the internal FG signal of the EFM frame sync (DEFS) and servo decode FG register (not shown) of the CD encoder By setting the value to be 1 pulse / revolution, the value of EFM frame sync (DEFS) number / revolution of the CD encoder can be read from the servo decode EFS count register 63.
Based on this value, the disk linear velocity can be calculated.
[0071]
As described above, in the second embodiment, the data synchronization rotation control circuit that controls the rotation of the rotary motor in synchronization with the recorded data signal, the phase synchronization circuit that is phase-synchronized with the data signal, and the phase synchronization A synchronous detection circuit for detecting that the circuit is in a synchronous state and outputting a lock signal; a frequency generating means for outputting an FG signal having a frequency proportional to the rotational speed of the rotary motor; and a predetermined motor according to the FG signal. FG rotation control circuit for controlling the rotation speed of the motor, and when the lock signal is obtained, the rotation motor is driven by the data synchronous rotation control circuit, and when the lock signal is not obtained, the rotation is performed by the FG rotation control circuit. The motor is driven.
Accordingly, when data synchronization cannot be transiently achieved due to shifting at the time of access, the FG control mode is automatically selected. When data synchronization is established, the data synchronous rotation control mode is set and The same effect as in the first embodiment can be obtained.
[0072]
Third Embodiment In the previous second embodiment, in the FG / DEC mode, as a condition for switching to the DEC mode, among the FG / DEC / WBL modes described in the first embodiment, The control related to automatic switching between the DEC mode and the WBL mode has been described.
In the third embodiment, the FG / DEC / WBL mode described in the previous first embodiment is related to the switching operation of the FG / DEC mode. In particular, as a condition for switching to the DEC mode, This is an operation for receiving the TON signal described in the first embodiment.
If the TON signal is active, the light beam is in the track tracking state, so that the data EFM can be obtained stably.
[0073]
The DPLOCK signal can be prevented from entering the DEC transition condition by setting the DPLMSK signal of the 0x80 register shown in FIG. 5 to “1”.
The reason for using the TON signal as a condition instead of the DPLOCK signal is as follows.
When jumping on a track, such as when accessing, if the light beam happens to be on the track, the data EFM is obtained only for a certain period, so the PLL may lock.
However, in this state, since the light beam is not tracking, this state does not last long.
In such a case, it is assumed that it is often more stable to continue the FG control.
[0074]
Therefore, in the third embodiment, a data synchronous rotation control circuit that performs rotation control of the rotary motor in synchronization with the recorded data signal, and an FG signal having a frequency proportional to the rotational speed of the rotary motor are output. A frequency generator and an FG rotation control circuit for controlling the motor to a predetermined number of revolutions according to the FG signal are provided, and when the optical beam of the optical disk apparatus is in a tracking state for tracking the track of the disk, data synchronous rotation The rotation motor is driven by the control circuit, and at other times, the rotation motor is driven by the FG rotation control circuit.
Therefore, even when accessing, it is possible to automatically shift to the data synchronous rotation control after obtaining stable data, and the same effect as in the case of the first embodiment can be obtained.
[0075]
Fourth Embodiment In the third embodiment, the operation for receiving the TON signal described in the first embodiment has been described as the condition for switching to the DEC mode.
In the fourth embodiment, the DPLOCK signal and the TON signal are used as the conditions for switching to the DEC mode.
As described above, by setting the automatic switching condition of the mode, the recorded data (EFM) signal can be obtained completely stably, and then the mode can be shifted to the DEC mode. Compared to the case of this form, more stable operation is possible.
[0076]
Fifth Embodiment In the first embodiment, the automatic switching of the DEC / WBL mode in the FG / DEC / WBL mode, and the FG / DEC in the second to fourth embodiments. Each automatic mode switching was explained.
In the fifth embodiment, the operation is related to automatic switching of the FG / WBL mode.
The operation in the FG / WBL auto mode has been described with reference to FIG. 13 as an example.
Here, the operation in the FG / WBL mode when there is no recording data will be described.
[0077]
FIG. 16 is a time chart for explaining the operation in the FG / WBL mode when there is no recording data in the rotary motor control device of the present invention. The reference numerals given to the respective waveforms in the figure correspond to the code positions in FIG.
[0078]
In FIG. 16, the FG mode and the WBL mode are based on the TON signal indicating that the tracking servo is on, and the FGLOCK signal for detecting that the FG servo system detected rotational speed is within ± 30% of the target rotational speed. This shows a case where automatic switching between and is performed.
In the FG / WBL mode, switching between rotation control using an FG signal and rotation control using a wobble signal is performed.
As a condition for shifting to the WBL mode, for example, it is assumed that it is within ± 30% of the target rotational speed during FG control.
The reason for this is that, as described above, the wobble signal is generally detected through a narrow band-pass filter (BPF) in order to improve the S / N ratio. This is because the wobble signal frequency may deviate from the passband of the bandpass filter and may not be detected.
[0079]
Therefore, in the fifth embodiment, the FG control is performed to enter the target rotation within a predetermined range (for example, ± 30%), and then the WBL control is performed.
However, if such an operation is to be realized by manual operation of the CPU, it is necessary to frequently measure the FG cycle and determine that this cycle is within a predetermined range, which increases the burden on the CPU. It is difficult to rotate at high speed.
As a result, it becomes difficult to increase the recording / reproducing speed of the drive device.
On the other hand, in the fifth embodiment, since automatic control is employed, the burden on the CPU is reduced and speeding up is easily realized.
[0080]
Therefore, in the fifth embodiment, a meandering synchronous rotation control circuit for controlling the rotation of the rotary motor in synchronization with the meandering of the guide groove of the disk and an FG signal having a frequency proportional to the rotational speed of the rotary motor are output. And an FG rotation control circuit for controlling the motor to a predetermined rotational speed in accordance with the FG signal. When the frequency of the FG signal is outside the predetermined range, the rotary motor is driven by the FG rotation control circuit. When within the predetermined range, the rotary motor is driven by the meandering synchronous rotation control circuit.
Therefore, rotation control at the time of access with a recordable disc can always be performed stably, and the same effect as in the case of the first embodiment can be obtained.
[0081]
Sixth Embodiment In the first embodiment, the automatic switching of the DEC / WBL mode in the FG / DEC / WBL mode, and the FG / DEC in the second to fourth embodiments. Regarding the automatic switching of the modes, further, in the fifth embodiment, the operation related to the automatic switching of the FG / WBL mode has been described.
The sixth embodiment is characterized in that the loop filter is shared in the FG mode and the WBL mode in the previous fifth embodiment.
[0082]
FIG. 17 is a functional block diagram showing an example of an embodiment of the main configuration of the gain correction circuit in the FG mode. The reference numerals in the figure are the same as those in FIG. 1, 71 is a period detector, 72 is a first gain setting unit, 73 is a pulse generator, 74 is a second gain setting unit, 75 is a loop filter, and 76 is gain correction. , 77 is a total gain setting unit, 78 is a clipping circuit, 79 is a PWM (pulse width modulation) unit, 80 is an adder, and KF, KFL, KL, K1, and K2 are set gains.
[0083]
The gain setting shown in FIG. 17, the setting gain KF for the first gain setting unit 72, and the setting gain KFL for the second gain setting unit 74 are set in the servo gain first register (not shown). Is done by.
The set gain KL to the gain correction unit 76 and the set gains K1 and K2 to the total gain setting unit 77 are respectively sent to a servo gain second register (not shown) and a servo gain third register (not shown). It is done by setting.
Note that the integration unit (loop filter) surrounded by a broken line is shared by the FG mode system and the WBL mode system, and integration data during integration is inherited between the modes.
[0084]
In the FG mode, as shown in FIG. 17, the difference between the FGIN cycle and the target cycle is obtained.
The motor control output MPWM is output in accordance with this difference and the result obtained by accumulating the difference and applying the gain.
In this way, by integrating the period difference (frequency difference), the low-frequency gain of the rotation control loop can be increased, and precise control becomes possible.
This integration unit may be particularly called a loop filter.
[0085]
FIG. 18 is a functional block diagram showing an example of an embodiment of the main configuration of a gain correction circuit in the WBL mode. The reference numerals in the figure are the same as those in FIGS. 1 and 17, 81 is a speed difference detection unit, 82 is a second gain correction unit, 83 is a clip circuit, 84 is a phase difference detection unit, and 85 is a third gain correction unit. , 86 are clip circuits, 87 and 88 are adders, and N and Kp are gains to be set.
[0086]
As shown in FIG. 18, in the WBL mode, the setting gain N for the second gain correction unit 82 and the setting gain Kp for the third gain correction unit 85 are respectively set to servo gain second registers (not shown). ), By setting to a servo gain third register (not shown).
And also in this WBL mode, the loop filter of previous FIG. 17 is used in common.
In the WBL mode, the frequency (rotational speed) and phase of the wobble signal (WBLIN) are compared with those of the reference pulse (ESFS: encoder EFM frame sync).
The reference pulse ESFS is generally generated from a reference oscillator.
[0087]
The compared speed difference and phase difference are respectively added with gain.
The integration unit (loop filter) integrates the result of adding the speed difference system and the phase difference system.
This integrated output and the original addition result are further added, multiplied by a gain, and a motor control output MPWM is output.
The loop gain characteristic of the WBL mode is as shown in FIG.
[0088]
FIG. 19 is a diagram illustrating an example of loop gain characteristics in the WBL mode.
[0089]
FIG. 19 shows a Bode diagram.
As shown in FIG. 19, the phase system amplifies the low frequency range, and the loop filter system amplifies the low frequency.
This loop filter improves the low-frequency control characteristics.
As described above, in the sixth embodiment, the integration loop filter is commonly used in the FG mode and the WBL mode. Therefore, the circuit is simplified, and precise control characteristics can be obtained in any mode.
Furthermore, since the integrated value is taken over, the control at the time of mode switching is not disturbed, and a smooth transition is possible.
[0090]
As described above, in the sixth embodiment, in the rotary motor control device described in the previous fifth embodiment, a frequency comparator that compares the frequency of the FG signal with the target frequency of the FG rotation control circuit. A phase comparator that compares the phase of the meandering signal with the phase of the reference signal of the meandering synchronous rotation control circuit, and an integrator that integrates one of the comparison results of the two comparators. When the rotary motor is driven by the FG rotation control circuit, the rotary motor is driven according to the output of the frequency comparator and the result of integrating the output by the integrator, and the rotary motor is driven by the meandering synchronous rotation control circuit. When doing so, the rotary motor is driven in accordance with the output of the phase comparator and the result of integrating the output by the integrator. Therefore, a common loop filter can be used in the two control modes, and in addition to the reduction in circuit cost, the integrated value can be taken over, so that the control at the time of switching is stabilized.
[0091]
Seventh Embodiment This seventh embodiment is characterized in that it is possible to shift to the DEC mode in addition to the FG / WBL mode described in the fifth embodiment. Yes.
The operation in the FG / DEC / WBL mode when recording data exists has been described with reference to FIG.
Here, the operation in the FG / DEC / WBL mode when there is no recording data will be described.
[0092]
FIG. 20 is a time chart for explaining the operation in the FG / DEC / WBL mode when there is no recording data in the rotary motor control device of the present invention. The reference numerals given to the respective waveforms in the figure correspond to the code positions in FIG.
[0093]
As shown in FIG. 20 and FIG. 11 above, when the DPLOCK signal is active, the DEC mode is set, the DPLOCK signal is inactive, and the FG signal is within a predetermined range (for example, ± 30%) of the target cycle. When the DPLOCK signal is inactive and the FG signal is outside a predetermined range (for example, ± 30%) of the target period, the mode is switched to the FG mode.
By this automatic mode switching, stable control is always automatically selected and set even in a disc in which recorded and unrecorded portions are mixed, reducing the burden on the CPU.
Therefore, the speed can be increased.
[0094]
Eighth Embodiment In the eighth embodiment, at the beginning of acceleration, a kick acceleration mode is first set, the rotary motor is accelerated with a predetermined power, and several FG pulses (for example, two) can be obtained. At that time, the FG mode (from the kick acceleration mode to the FG mode) is switched.
The setting of the automatic switching mode (KICK to FG auto mode) from the kick acceleration mode to the FG mode has been described with reference to FIG.
[0095]
Thus, the reason for setting the kick acceleration mode at the beginning of acceleration is that if the FG mode is set from the beginning, the FG cycle cannot be measured and acceleration cannot be performed while the FG pulse cannot be obtained. Because.
If this operation is performed by the CPU, it must be monitored by software whether or not an FG pulse has occurred, and the burden on the CPU increases, making it difficult to rotate at high speed.
[0096]
As described above, in the eighth embodiment, the kick mode setting for setting the kick mode for accelerating the rotary motor with a predetermined power in the rotary motor control device described in the second to seventh embodiments. Means are provided so that the rotary motor is accelerated by the kick mode from the stopped state of the rotary motor, and when the FG signal pulse reaches a predetermined number of revolutions, the rotary motor is controlled by the FG rotation control circuit.
Therefore, in addition to the effects of the second to seventh embodiments, a stable start can be performed without increasing the burden on the CPU.
[0097]
Ninth Embodiment This ninth embodiment is control when the motor is decelerated from the rotating state. In the rotating state of the rotary motor, the brake mode is set and the motor is decelerated at a predetermined power. When the reverse rotation is detected by inputting the REVDET signal, it automatically shifts to the stop mode (from the brake mode to the stop mode).
The setting of the automatic switching mode (BRAKE to STOP auto mode) from the brake mode to the stop mode has also been described with reference to FIG.
According to the ninth embodiment, when the reverse rotation is detected by setting the brake mode in the rotating state of the rotary motor, decelerating at a predetermined power, and inputting the REVDET signal, the stop mode is automatically set. In addition to the effects of the second to eighth embodiments described above, the inconvenience that the burden is large when performed by the CPU is solved and the operation can be stably stopped. .
[0098]
Tenth Embodiment The tenth embodiment is characterized in that when the frequency of the FG signal is higher than the target value by a predetermined range, a short brake signal is output to decelerate the motor.
[0099]
When decelerating the motor in the FG mode, FG / WBL mode, FG / DEC mode, or brake mode described earlier, the motor control output MPWM in the reverse rotation direction is input to the motor driver. A current in the reverse rotation direction flows.
However, the motor generally generates an electromotive force in the reverse direction (counterelectromotive force) proportional to the number of rotations when rotating, and when a current flows in the reverse rotation direction, the reverse electromotive force generated by the counter electromotive force is generated. A large current flows due to the addition of currents in the rotational direction.
As a result, power consumption increases and the heat generation of the motor coil and motor driver also increases.
[0100]
Conventionally, a control method for applying a self-brake by short-circuiting motor coil ends is generally used.
However, the deceleration control is necessary not only for stopping the motor but also for rotating the CLV when the optical head is accessed in the outer circumferential direction.
In the tenth embodiment, a short brake can be applied at a certain deceleration.
In addition, at the time of deceleration accompanied by access, since the target rotation speed of the FG control is set, the short brake may be released when the short brake is applied and the target rotation speed is approached.
[0101]
As described above, in the tenth embodiment, in the rotary motor control device described in the second to ninth embodiments, a short brake signal output for generating a brake signal for short-circuiting the coil of the rotary motor. Means are provided to output a short brake signal when the frequency of the FG signal is higher than the target value by a predetermined range.
Therefore, in addition to the effects of the second to ninth embodiments, deceleration control with low power consumption is realized without increasing the load on the CPU.
[0102]
Eleventh Embodiment The eleventh embodiment is related to the invention of claim 1. In the first to tenth embodiments described above, switching of the FG / DEC / WBL mode has been described. The eleventh embodiment relates to the WBL mode and the AX mode.
[0103]
In the AX mode, the phase comparison between the ATIP synchronization signal (ASYNC) obtained by decoding the ATIP signal and the reference signal ESFS (standard speed 75 Hz) is performed, and the rotary motor is driven by this output.
The ATIP synchronizing signal (ASYNC) is embedded in the meandering groove of the disk by FM modulating the wobble signal, and has a frequency of 75 Hz at the standard speed.
Therefore, in this AX mode, the ATIP synchronization signal (ASYNC) and the reference signal ESFS are phase-synchronized to perform rotation control.
Therefore, if the reference signal ESFS is set as the reference timing signal for the write data, the write data can be written with the position on the disc completely matched.
[0104]
FIG. 21 is a functional block diagram showing an example of an embodiment of the main configuration of a circuit in the AX mode. The reference numerals in the figure are the same as those in FIG. 1, 91 is a phase comparator (PD), 92 is a phase corrector (DCO), 93 is a changeover switch, and 94 is a WBL mode circuit.
[0105]
FIG. 22 is a functional block diagram showing another example of the configuration of the main part of the circuit configuration in the AX mode. The reference numerals in the figure are the same as those in FIG. 21, wherein 95 indicates an amplifier, 96 indicates a 1/3 frequency divider, and 97 indicates a phase comparator (PD).
[0106]
In the WBL mode, the encoder EFM frame sync signal (EEFS) is used as a reference clock, and in the AX mode, the reference is determined according to the phase difference between the encoder subcode sync signal (ESFS) and the detected ATIP sync signal (ASYNC). Change the clock phase.
Since the delay from the ATIP sync signal on the disk to the detected ATIP sync signal is caused by the FSK demodulator and the ATIP sync detection circuit, the delay value may be set.
[0107]
FIG. 23 is a time chart for explaining the operation in the FG / WBL mode at the start of writing. The reference numerals given to the waveforms in the figure correspond to the reference positions in FIG.
[0108]
FIG. 24 is a time chart for explaining the operation in the FG / WBL mode at the end of writing. The reference numerals given to the waveforms in the figure correspond to the reference positions in FIG.
[0109]
In the eleventh embodiment, the WBL / AX mode is switched to the WBL mode until slightly before the position (address) where writing is started (for example, one sector before). Enter mode. The reason is that in the WBL mode, the wobble signal can be controlled at a higher speed by the higher frequency (22 KHz), and the settling can be performed quickly. Keep it in sync. Then, immediately before the start of writing, the mode is shifted to the AX mode and writing is started. Also in the eleventh embodiment, when the CPU switches between the WBL mode and the AX mode, the CPU frequently monitors the current address to determine whether the predetermined number before the write start address has been reached. Therefore, the inconvenience that the burden is large and the speeding up is limited is solved. That is, high-speed control by meandering synchronous rotation control is possible before recording starts, and address synchronization can be achieved during recording, so that precise recording control can be performed and the same as in the first embodiment. An effect is also obtained.
Twelfth Embodiment This twelfth embodiment relates to the invention of claim 1. In the previous eleventh embodiment, switching of the WBL / AX mode has been described. The twelfth embodiment is an improvement of the AX mode itself.
[0110]
In the twelfth embodiment, a phase comparison between the ATIP synchronization signal (ASYNC) and the reference signal ESFS (standard speed 75 Hz) is performed, and a variable frequency oscillator that varies the frequency based on the comparison result is provided. It is characterized in that the output is a WBL mode reference signal.
[0111]
Since the variable frequency oscillator used in this case is a digital circuit, in this embodiment, the variable frequency oscillator is called a DCO (Digital Controlled Oscillator). With this configuration, the frequency of the reference signal output from the DCO changes according to the phase comparison result between the ATIP synchronization signal (ASYNC) and the reference signal ESFS, and as a result, the ATIP synchronization signal (ASYNC) ) And the reference-synchronized rotation control of the reference signal ESFS. When shifting to the WBL mode, instead of the DCO output, the WPL mode system reference signal EEFS (encoder EFM frame sync signal: 7.35 KHz at standard speed) may be used as the WBL mode system reference signal. Such switching can be realized by a simple switch. As described above, according to the twelfth embodiment, the AX mode can be realized by using the WBL mode system in common. Even during the AX mode, since the WBL mode system is closed in synchronization with the wobble signal, high-bandwidth control is possible.
Thirteenth Embodiment This thirteenth embodiment relates to the invention of claim 1.
[0112]
The thirteenth embodiment is characterized in that in the WBL / AX mode, the mode automatically shifts to the WBL mode after the end of recording.
The reason is that the AX mode described in the previous eleventh embodiment is an unnecessary mode except during recording, and therefore it is preferable to quickly enter the WBL mode when recording is completed.
As described above, after the recording is completed, it is possible to return to the WBL mode without imposing a burden on the CPU by automatically shifting to the WBL mode.
Fourteenth Embodiment In the first to thirteenth embodiments, in connection with the automatic switching operation of the FG / DEC / WBL / AX mode, the load on the CPU is reduced by the transition of the auto mode. explained.
According to each of these embodiments, it is possible to reduce the code size of software to be implemented (actually called ROM since it is built in the ROM), and by using a small capacity ROM Cost reduction is also realized.
The fourteenth embodiment relates to the separation of the LSI chip of the drive device that performs the above operation.
[0113]
A circuit that performs rotation control in synchronization with recording data and a circuit that outputs a PLL and PLL lock state (signal DPLOCK) that are phase-synchronized with recording data are generally built in the CD-DSP.
This chip is widely used in CD-ROM devices and is produced in very large quantities, so the cost is low.
Further, other FG, WBL, AX auto mode, etc. are made into chips exclusively for CD-R.
With this configuration, the control of the DEC mode itself can be left to the CD-DSP and does not have to be built in the CD-R chip side, so the cost of the CD-R control chip can be reduced. Realized.
Therefore, as a total, a low-cost CD-R drive can be obtained.
[0114]
【The invention's effect】
According to the first aspect of the present invention, there is provided a rotation motor control device for a recordable optical disk apparatus, and a meandering synchronous rotation control circuit for performing rotation control of the rotation motor based on a meander signal generated corresponding to the meandering of the guide groove of the disk. And a synchronization signal detection circuit for detecting an address synchronization signal arranged as meandering of the guide groove at a predetermined distance in the linear direction of the guide groove, and a phase for comparing the phases of the address synchronization signal and the reference clock signal An address-synchronized rotation control circuit having a comparator and a variable frequency oscillator that outputs a reference signal having a frequency corresponding to the comparison result of the phase comparator, and supplying the reference signal to the meandering synchronous rotation control circuit The meandering synchronous rotation control circuit controls the rotary motor based on the meandering signal until a predetermined position before the recording start address, It is subjected during the recording operation from the front only position, so as to control the rotary motor on the basis of the meandering signal and the reference signal. Therefore, it is possible to perform high-speed control by meandering synchronous rotation control before recording starts, and during recording, address synchronous control can be performed while maintaining the high-speed controllability of meandering synchronous rotation control mode, and precise recording control is possible. It can be carried out.
[0117]
According to a second aspect of the present invention, there is provided a recordable optical disk device comprising the rotary motor control device according to the first aspect, wherein the data synchronous rotation control circuit performs rotation control of the rotary motor in synchronization with the recorded data signal; The first digital signal processing LSI includes a phase synchronization circuit that is phase-synchronized with the data signal, and a synchronization detection circuit that detects that the phase synchronization circuit is in synchronization and outputs a lock signal. This processing means is built in the second digital signal processing LSI. Therefore, the control of the DEC mode itself can be left to the CD-DSP and does not have to be built in the CD-R chip, so that the cost of the CD-R control chip can be reduced. In addition, the automatic switching of the control mode allows stable rotation control at all times and does not increase the CPU burden associated with the switching. Therefore, the firmware size can be reduced, the cost can be reduced, and the overall cost of the optical disk apparatus can be reduced. A high-speed device is realized.
[0118]
According to a fourth aspect of the present invention, there is provided a rotation motor control device for an optical disk, the recordable optical disk device comprising the rotation motor control device according to any one of the first to third aspects, wherein the rotation control of the rotation motor is performed in synchronization with a recorded data signal. A data synchronization rotation control circuit for performing phase synchronization, a phase synchronization circuit for phase synchronization with a data signal, and a synchronization detection circuit for detecting that the phase synchronization circuit is in synchronization and outputting a lock signal. The other processing means is built in the second digital signal processing LSI.
Therefore, the control of the DEC mode itself can be left to the CD-DSP and does not have to be built in the CD-R chip, so that the cost of the CD-R control chip can be reduced.
In addition, the automatic switching of the control mode allows stable rotation control at all times and does not increase the CPU burden associated with the switching. Therefore, the firmware size can be reduced, the cost can be reduced, and the overall cost of the optical disk apparatus can be reduced. A high-speed device is realized.
[Brief description of the drawings]
FIG. 1 is a functional block diagram showing an example of an embodiment of a main part configuration of a rotary motor control device for an optical disk according to the present invention.
FIG. 2 is a functional block diagram showing an example of a configuration of a main part of a one-chip LSI in which functions for a CD-R disk drive device are integrated.
FIG. 3 is a functional block diagram showing an example of a configuration of a main part of a one-chip LSI in which functions for a CD-R disk drive device are integrated.
4 is a diagram showing interface signals in the rotary motor control device 20 shown in FIG. 2; FIG.
FIG. 5 is a diagram illustrating an example of a TON signal and a DPLMSK signal register.
FIG. 6 is a diagram illustrating an example of an SVMODE signal register.
FIG. 7 is a diagram illustrating an example of a KICDAT signal register.
FIG. 8 is a diagram illustrating an example of an FGMTH signal and an FGMTL signal register.
FIG. 9 is a diagram showing an example of manual mode setting for the servo mode of the spindle motor.
FIG. 10 is a diagram illustrating an example of setting an auto mode for a servo mode of a spindle motor.
FIG. 11 is a time chart for explaining the operation in the FG / DEC / WBL mode when there is recording data for the rotary motor control device of the present invention;
FIG. 12 is a functional block diagram showing an example of an embodiment of a main configuration of a WBL mode circuit;
FIG. 13 is a time chart for explaining the operation in the FG / DEC auto mode for the rotary motor control device of the present invention;
FIG. 14 is a functional block diagram showing an example of an embodiment of a main part configuration of an FG mode circuit;
FIG. 15 is a functional block diagram showing an example of an embodiment of a main part configuration of an interface circuit of a CD encoder.
FIG. 16 is a time chart for explaining the operation in the FG / WBL mode when there is no recording data in the rotary motor control device of the present invention.
FIG. 17 is a functional block diagram showing an example of an embodiment of the main configuration of a gain correction circuit in the FG mode.
FIG. 18 is a functional block diagram showing an example of an embodiment of a main configuration of a gain correction circuit in the WBL mode.
FIG. 19 is a diagram illustrating an example of loop gain characteristics in the WBL mode.
FIG. 20 is a time chart for explaining the operation in the FG / DEC / WBL mode when there is no recording data in the rotary motor control device of the present invention.
FIG. 21 is a functional block diagram showing an example of an embodiment of a main configuration of a circuit in an AX mode.
FIG. 22 is a functional block diagram showing another example of the configuration of the main part of the circuit configuration of the AX mode.
FIG. 23 is a time chart for explaining the operation in the FG / WBL mode at the start of writing.
FIG. 24 is a time chart for explaining the operation in the FG / WBL mode at the end of writing;
FIG. 25 is a functional block diagram showing an example of a main part configuration of an optical disc drive.
[Explanation of symbols]
20 Rotating Motor Control Device 21 Clock Generator 22 Clock Synthesizer 23 CIRC Encoder 24 Subcode Operator 25 Sector Processor 31 Motor Control Circuit 32 CD-DSP LSI
32a decode PLL
32b Frequency control unit 32c EFM synchronization lock unit 32d CLV control unit 33 Motor driver 34 Filter 35 Switch 36 Midway switch

Claims (2)

A rotary motor control device in a recordable optical disk device;
A meandering synchronous rotation control circuit for controlling the rotation of the rotary motor based on a meandering signal generated corresponding to the meandering of the guide groove of the disk;
A synchronization signal detection circuit for detecting an address synchronization signal arranged as meandering of the guide groove for each predetermined distance in the linear direction of the guide groove;
A phase comparator that compares phases of the address synchronization signal and a reference clock signal, and a variable frequency oscillator that outputs a reference signal having a frequency corresponding to a comparison result of the phase comparator, and meandering the reference signal An address synchronous rotation control circuit for supplying to the synchronous rotation control circuit,
The meandering synchronous rotation control circuit is:
The rotating motor is controlled based on the meandering signal until a predetermined position before the recording start address, and the rotating motor is controlled based on the meandering signal and the reference signal from the predetermined position before the recording start address to during the recording operation. A rotary motor control device. A recordable optical disk device comprising the rotary motor control device according to claim 1,
A data synchronous rotation control circuit that performs rotation control of the rotary motor in synchronization with the recorded data signal;
A phase synchronization circuit that is phase-synchronized with the data signal;
A synchronization detection circuit that detects that the phase synchronization circuit is in a synchronized state and outputs a lock signal is incorporated in the first digital signal processing LSI;
The other processing means is incorporated in the second digital signal processing LSI.

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