JP3981559B2 - Optical disc apparatus and disc discrimination method thereof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical disc apparatus for recording and reproducing information on a disc using a semiconductor laser and a disc discriminating method thereof, and more particularly to a discriminating technique for a plurality of optical discs having different disc structures and disc format structures.
[0002]
[Prior art]
Conventional examples of recordable optical disks include CD-R / RW and DVD-R / RW / RAM. Among these discs, CD-type CD-R / RW and DVD-type DVD-R / RW / RAM have physical properties such as disc thickness, track pitch, size of recording mark, and laser wavelength when recording on a medium. Structural characteristics are very different. Also, the same DVD system DVD-R / RW and DVD-RAM have different formats, particularly address configurations.
[0003]
As a configuration of a disk device that performs recording / reproduction with respect to the plurality of recordable optical disks, a configuration in which a pickup and a signal processing LSI that match each characteristic are considered.
[0004]
Japanese Patent Laid-Open No. 2001-243696 discloses an apparatus for optically discriminating the types of information recording media including a CD-R. That is, the first and second laser diodes that respectively emit a plurality of light beams having different wavelengths and the reflected light from the optical disk of each emitted light beam are respectively received and correspond to the received reflected light. A discriminating device including a pickup that outputs a detection signal and a servo IC that discriminates the type of the optical disk based on the ratio between the received light signals is disclosed.
[0005]
[Problems to be solved by the invention]
In an optical disk apparatus combining a pickup, a signal processing circuit, and an LSI that are suitable for each disk, since individual functions are combined, there is no problem in obtaining predetermined characteristics, that is, recording / reproducing characteristics for various disks. Since the number of parts increases and the shape of the pickup and the like becomes large, there arises a problem that the apparatus becomes too large due to the structure of the apparatus, and the board does not fit in the normal size. Of course, the cost also increases. Furthermore, problems such as a decrease in reliability associated with an increase in the number of components and heat generation associated with an increase in power consumption occur. For this reason, it becomes a subject to suppress the number of parts as much as possible and to achieve miniaturization.
[0006]
In addition, recording / reproduction is performed on a plurality of discs such as CD-ROM, R, RW, DVD-ROM, R, and RW. However, since these use different laser wavelengths, substrate thicknesses, and formats, an address detection method. Etc., and it is necessary to select an optical or electrical circuit to cope with each disk. Therefore, there arises a problem that the disc discrimination time until the recording / reproducing operation is extended. Therefore, how to discriminate in a short time is a problem.
[0007]
Further, the technique described in Japanese Patent Laid-Open No. 2001-243696 cannot discriminate DVD-RAM.
[0008]
An object of the present invention is to provide a technique for discriminating a single-layer disc and a multi-layer disc.
Another object of the present invention is to discriminate discs that can discriminate discs more accurately by discriminating whether chucking is normal or mischucking and discriminating only when chucking is normal. To provide technology. Another object of the present invention is to provide a discrimination technique capable of discriminating at least DVD-RAM, DVD-R, and DVD-RW.
[0009]
[Means for Solving the Problems]
In order to achieve the object of the present invention, in the first invention, when the objective lens of the optical pickup is swept with respect to the optical disc, the number of S-shaped focus error signals detected in the sweep step of the objective lens is calculated. Counting is performed, and the number of layers on the recording surface is determined from the number of S-shaped focus error signals to determine the number of layers of the optical disk.
[0010]
In the second invention, in the first invention, before sweeping the objective lens, it is discriminated that the disc is a DVD disc, and it is discriminated that the chucking of the optical disc is normal.
[0011]
In the third aspect of the invention, it is determined that the disc is a DVD disc, the DVD disc is a single layer disc, and a first push-pull tracking error signal is output at a first predetermined radius position of the disc. And acquiring a second push-pull tracking error signal at a second predetermined radial position that is greater than the first radial position, and the second push-pull tracking error signal amplitude is the second push-pull tracking error signal. If it is larger than the amplitude, it is determined as a DVD-RAM.
[0012]
In the fourth invention, in the third invention, the control data is read, and it is discriminated whether it is DVD-RAM 1 or DVD-RAM 2 from the disc type of the control data.
[0013]
In the fifth invention, the disc is discriminated as a DVD disc, the disc is discriminated as a single layer disc, and a first push-pull tracking error signal is output at a first predetermined radius position of the disc. And obtaining a second push-pull tracking error signal at a second predetermined radius position of the disc, computing the first and second push-pull tracking error signals, and calculating the DVD-R disc from the computation result. Is determined.
[0014]
According to a sixth aspect, in the fifth aspect, the control data is read and discriminated as DVD-R3.9, DVD-R4.7-A, or DVD-R4.7-G from the disc type of the control data. To do.
[0015]
In the seventh invention, the disc is discriminated as a DVD disc, the disc is discriminated as a single-layer disc, and a first push-pull tracking error signal is output at a first predetermined radius position of the disc. And acquiring a second push-pull tracking error signal at a second predetermined radius position of the disk, and determining that the sum of the amplitudes of the first and second push-pull tracking error signals is smaller than a predetermined value. If a phase difference tracking error signal is acquired at a predetermined position of the disk, one of the first and second push-pull tracking error signal amplitudes is smaller than a predetermined value, and the phase difference tracking When the tracking error signal amplitude is smaller than a predetermined value, it is determined as DVD-RW or + RW.
[0016]
In the eighth invention, in the seventh invention, if there is RPFI when discriminating between DVD-RW1.1 and DVD-RW1.0, discrimination is performed based on RPFI data, and there is no RPFI and there is RMD. In this case, the determination is made based on the RMD data, and if there is no RMD, the determination is made based on the LPP data.
[0017]
In the ninth invention, the disc is discriminated as a DVD disc, the disc is discriminated as a single-layer disc, and a first push-pull tracking error signal is output at a first predetermined radius position of the disc. And acquiring a second push-pull tracking error signal at a second predetermined radius position of the disk, and determining that the sum of the amplitudes of the first and second push-pull tracking error signals is smaller than a predetermined value. A phase difference tracking error signal is acquired at a predetermined position of the disk, and one of the first and second push-pull tracking error signal amplitudes is greater than a predetermined value, and the phase difference When it is determined that the tracking error signal amplitude of the system is greater than or equal to a predetermined value, it is determined as DVD-ROM or DVD-RW.
[0018]
In the tenth invention, in the ninth invention, the control data is read, and it is discriminated whether it is DVD-ROM or DVD-RW 1.1 from the disc type of the control data.
[0019]
In the eleventh aspect of the invention, the objective lens of the optical pickup is swept with respect to the optical disc at the first disc radial position to obtain the amplitude of the first S-shaped focus error signal, and at the second disc radial position. The objective lens of the optical pickup is swept with respect to the optical disc to obtain the amplitude of the second S-shaped focus error signal, and the amplitude of the first and second S-shaped focus error signals Is smaller than the predetermined value, it is determined that the chucking is abnormal.
[0020]
In the twelfth invention, the objective lens of the optical pickup is swept with respect to the optical disc at the first disc radial position to obtain the amplitude of the first S-shaped focus error signal, and at the second disc radial position. The objective lens of the optical pickup is swept with respect to the optical disc to obtain the amplitude of the second S-shaped focus error signal, and the amplitude of the first S-shaped focus error signal and the second When the difference from the amplitude of the S-shaped focus error signal is larger than a predetermined value, it is determined that the chucking is abnormal.
[0021]
In the thirteenth invention, it takes from the start of sweeping the objective lens of the optical pickup to the optical disk at the first disk radial position to the predetermined position of the first S-shaped focus error signal. After the first time is measured and the objective lens of the optical pickup is started to sweep with respect to the optical disk at the second disk radial position, the predetermined S-shaped focus error signal is determined in advance. The second time required to reach the position is measured, and if the difference between the first time and the second time is greater than a predetermined value, it is determined that the chucking is abnormal.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
  Embodiments of the present invention will be described below with reference to the drawings using examples. FIG. 1 is a block diagram showing an embodiment of an optical disk apparatus according to the present invention. As the recordable optical disk 1 used in this embodiment, there are five types of disks: CD-R, CD-RW, DVD-R, DVD-RW, and DVD-RAM. Needless to say, the present optical disk apparatus can also reproduce a reproduction-only DVD-ROM and CD-ROM. The recording apparatus is a spindle that rotates the optical disk 1.motor2. Optical pickup 3 for irradiating the optical disc 1 with laser light for recording / reproducing information, optical pickup3FromofInput playback signalFrom the RF front end 4Composed.
[0023]
  The recording device further includesUpon receiving this RF front end 4 signal,lightdisk1It comprises a digital signal processing circuit 5 for extracting the above data and a microcomputer 6 for controlling these circuits. The RF front end 4 and the digital signal processing circuit 5 are usually composed of an LSI. The servo system signal is generated by the RF front end 4, and the digital signal processing circuit 5TheControlled.
[0024]
For recording signal control, necessary information is sent from the digital signal processing circuit 5 to the laser diode driver 13 mounted on the optical pickup 3, and the laser diode driver 13 receives the first laser diode 11 and the second laser diode. 12 is controlled. The first laser diode 11 is used, for example, for an optical disk for CD, and the second laser diode 12 is used for an optical disk for DVD.
[0025]
Recording waveform control is performed in the laser diode driver 13 in this embodiment. Control signals necessary for the laser diode driver 13 are generated corresponding to the respective disks and formats to control the laser diode driver 13. In addition, power control signals and the like are controlled by blocks corresponding to the respective disks.
[0026]
  The disc discrimination processing operation by the optical disc recording / reproducing apparatus according to the present invention will be described below with reference to flowcharts.To do. FIG.FIG. 5 is a flowchart showing a schematic processing operation of the disc discrimination method according to the present invention. Figure2In step 401, it is determined whether the optical disc is a DVD optical disc or a CD optical disc (hereinafter, the optical disc is simply referred to as a disc). If the disc is a CD disc, the CD disc is determined in step 402. By this determination, as shown in steps 403, 404, and 405, it can be determined whether each is a CD-ROM, a CD-R, or a CD-RW.
[0027]
  If it is determined in step 401 that the disc is a DVD-type disc, it is determined in step 406 whether the disc is a single-layer disc, a dual-layer disc, or a multi-layer disc of more than that. As a result, as shown in steps 407 and 408, it can be determined whether the disc is a DVD-ROM single-layer disc or a DVD-ROM dual-layer disc. Among the single-layer discs, the discs other than the DVD-RAM, DVD-R, and DVD-RW are discriminated in step 411. In step 411, the DVD-RAM 1 and the DVD-RAM 2 are discriminated. As shown in the steps 412 and 413, the DVD-RAM 1 or the DVD-RAM2I understand.
[0028]
  A DVD-R disc is discriminated in step 415. As a result, step 416˜418, DVD-R3.9 (DVD-R ver. 1.0), DVD-R4.7-A (DVD-R ver. 2.0 for Authoring), DVD-R4.7G, respectively. (DVD-R ver. 2.0 for General). For DVD-RW and + RW discs, the determination is made at step 421. As a result, as shown in steps 422 and 423, it is discriminated as DVD-RW 1.0 (DVD-RW ver. 1.0) or DVD-RW 1.1 (DVD-RW ver. 1.1).
[0029]
Hereinafter, the processing operation of the disk discrimination method shown in FIG. 2 will be described in detail. In this embodiment, when disc determination is performed, it is determined whether or not chucking is normal, and disc determination is performed when the disc is normal. This will also be described in detail.
FIG. 3 is a flowchart for explaining the operation of discriminating between the CD-type optical disc and the DVD-type optical disc and the CD-type disc type discrimination processing.
In step 501, the apparatus is turned on, and the optical pickup is moved to the rezero position of the optical disk, that is, to the position where the radius r of the optical disk is 23.7 mm. However, at this point, the optical disk has not yet rotated. In step 502, the optical disk is irradiated with a DVD laser, and the return light is detected. In the case of a CD optical disk, the return light is hardly detected and is below a predetermined value. In the case of a DVD optical disk, it is considerably larger than the predetermined value. If the return light is equal to or smaller than the predetermined value in step 502, it is a CD disc or an optical disc is not loaded.
[0030]
If it is determined in step 502 that the CD system disk or the disk is not loaded, the CD laser is irradiated to the disk in step 503, and the return light is detected. In the case of a CD-type disc, return light of a predetermined value or more is detected. In this case, it is determined that the disc is a CD-type disc. That is, the detected return light is input to the microcomputer and compared with a predetermined threshold value by the microcomputer, and if it is larger than the threshold value, it is determined as a CD disk. If no return light is detected, it is determined that no disk is loaded, and therefore it is determined in step 504 that a disk is not loaded (not ready). If it is determined in step 503 that the disc is a CD-type disc, the sled is moved in step 505, and the optical pickup is adjusted so as to be positioned at a radius r = 25 mm of the disc. Next, the process moves to step 506, where the CD laser is irradiated again to detect the focus error signal. It is determined whether the amplitude of the detected focus error signal is greater than or equal to a predetermined value. If the amplitude is smaller than the predetermined value, it is determined in step 507 that a disc is not loaded (not ready).
[0031]
On the other hand, if the return light is greater than or equal to the predetermined value in step 502 and it is determined that the disc is a DVD-type disc, the process proceeds to step 510 to move the sled so that the optical pickup is positioned at a radius r = 25 mm. Adjust to. By changing the position of the pickup and irradiating the DVD laser, the presence or absence of the tilt of the disc can be seen. Next, in step 511, it is determined whether or not it is sufficiently chucked. If it is determined in step 511 that the chucking is OK, the disc is rotated, and again in step 512, the disc is irradiated with a DVD laser. If the return light is smaller than a predetermined value, it is determined as a CD disk.
[0032]
If it is determined in step 511 that there is a chucking mistake, if it is determined in step 512 that the disc is a CD-type disc, and if a CD laser is irradiated in step 506 and the return light is equal to or greater than a predetermined value, the CD-type disc If it is smaller than the predetermined value, it is determined in step 507 that no disc is loaded.
[0033]
  Next, in step 514, various data obtained so far are input to the microcomputer, and determination is made as described later. If it is determined in step 514 that there is a chucking mistake, not ready is obtained in step 515. If the chucking is good in step 514, the disc laser is irradiated to the disc in step 516 to detect the focus error signal amplitude. If the focus error signal amplitude is greater than or equal to a predetermined value, The CD disc is determined to be a light reflecting disc, and the process proceeds to step 517. In step 517, it is determined whether or not wobble synchronization is performed. That is, it is determined whether or not a wobble signal is detected. That is, when a wobble signal is detected, the clock signal is synchronized with the wobble signal by the PLL circuit. If the wobble signal cannot be detected in step 517, it is determined as a CD-ROM disc as shown in step 518. If a wobble signal is detected in step 517, it is determined as a CD-R disc as shown in step 519. If the amplitude of the focus error signal is smaller than the predetermined value in step 516, the disk is a low reflection disk and CD−Estimated RW, but for further clarity, step 520soA wobble signal is detected. If a wobble signal is detected, it is clear that wobble synchronization is being performed, so that it can be determined as a CD-RW disc in step 521.
[0034]
Next, a method for determining whether the chucking is good or bad (mischucking) in steps 511 and 514 will be described.
In the present embodiment, for example, CD-ROM, CDM-R, and CD-RW (CD-MRW) are discs that can determine a chucking failure, and DVD-RAM1 and DVD- RAM 2, DVD-ROM 1 layer, DVD-ROM 2 layer, DVD-R 3.95 GB, DVD-R 4.7 GB, DVD-RW, DVD- + RW 4.7 GB.
Mischucking detection will be described separately for an apparatus having a mechanical tilt sensor and an unequipped apparatus.
[0035]
First, detection of mischucking in a device not equipped with a mechanical tilt sensor will be described with reference to FIGS.
FIG. 4 is a diagram showing focus error signals detected on the inner and outer peripheral sides of the disc. First, when focus sweep is performed by moving the optical pickup to the rezero position on the inner circumference side, two focus error signals (hereinafter referred to as FE signals) are obtained. The first FE signal 601 is due to reflection on the disk substrate surface. The second FE signal 602 is an FE signal obtained by reflection from the recording surface of the disc. Further, after the optical pickup is moved in the outer circumferential direction of the disk, a focus sweep is performed to obtain an FE signal 603 reflected from the disk surface and an FE signal 604 reflected from the recording surface of the disk. Now, suppose that the maximum amplitude of the FE signal 602 is FE1, and the maximum amplitude of the FE signal 604 is FE2. Reference numeral 605 denotes an FOD (signal for driving an actuator for Focus Drive) curve. Furthermore, in the present embodiment, mischucking is determined by obtaining the S-curve time t11, t12, t21, t22 shown in the figure. t11 is the time between the focus sweep start point and the zero point of the FE signal 601; t21 is the time between the focus sweep start point and the zero point of the FE signal 603; t12 is the time between the zero points of the FE signal 601 and the FE signal 602; t22 is the time between zero points of the FE signal 603 and the FE signal 604.
[0036]
Conventionally, mischucking was detected only by the magnitude of the FE signal. However, in this method, the focal point of the disc recording surface is matched due to the tilt state of the disc at the time of mischucking, and the FE signal amplitude is normal chucking. A signal with a level comparable to that may be output, and mischucking could not be detected accurately. For this reason, in this invention, the time between S-curves is acquired.
[0037]
When the disc is normally chucked, the time from the focus sweep start time to the observation of the FE signal due to the reflection on the disc surface changes only about the disc surface shake and sweep speed variation even if the measurement position is moved. On the other hand, when the disc is mischucked, the disc is tilted, and therefore, when the measurement position is moved, the disc becomes larger than the previous time. That is, t21 is larger than t11. Therefore, mischucking detection is performed using this time difference. Further, the FE signal amplitude is also used in order to cope with a case where the time detection is wrong. In the mischucking state, the amplitude of the FE signal may increase, and the amplitude may be small. Such a mischucking state is determined. Depending on the disc, the wavelength dependency may be high, so when determining that the state is a mischucking state or a state where there is no disc, be sure to perform the measurement with a DVD laser and a CD laser.
The above measurement is performed at a position avoiding the BCA region (21.9 mm to 23.55 mm). Therefore, the measurement on the inner peripheral side is performed at the rezero position, and the measurement on the outer peripheral side is performed at a position having a radius of 23.75 mm.
[0038]
  FIG. 5 is a flowchart showing an embodiment of the mischucking detection operation according to the present invention. First, in step 701, the S-curve time t11, t12, and FE1 described with reference to FIG. 4 are measured. That is, for the focus sweep, the time from when the objective lens starts to move from a predetermined position to the center of the S-shaped focus error signal is measured. This time may be the time from when the objective lens starts to move from a predetermined position to the predetermined position of the S-shaped focus error signal. In step 702, the optical pickup is moved in the outer peripheral direction and adjusted so that the radius r is 23.75 mm. In step 703, S-curve time t21, t22, and FE2 are measured. In step 704, it is determined whether or not the values of FE1 and FE2 are larger than a predetermined value FEd. If the disc is mounted well, both FE1 and FE2 must be greater than a predetermined value. Therefore, when the values of FE1 and FE2 are equal to or smaller than the predetermined value FEd, the process proceeds to step 705, and there is no medium or mischucking.WhenTo be judged. If the values of FE1 and FE2 are larger than the predetermined value FEd (in the case of Y), it is determined in step 706 whether or not the absolute value of t11-t21 is smaller than the predetermined time tm. When the disk is mounted well, the values of t11 and t21 are substantially the same value, so the absolute value of t11-t21 is smaller than the predetermined time. Therefore, when the absolute value of t11-t21 is equal to or longer than the predetermined time tm (in the case of N), the process proceeds to step 705, where there is no medium or mischucking.WhenTo be judged. If the absolute value of t11-t21 is smaller than the predetermined time tm in step 706, the process proceeds to step 707.
In step 707, it is determined whether or not the absolute value of FE1-FE2 is smaller than a predetermined value FEm. If the absolute value of FE1-FE2 is equal to or greater than the predetermined value FEm (in the case of N), there is no medium or mischucking in step 705.WhenTo be judged. If it is determined in step 707 that the absolute value of FE1-FE2 is smaller than the predetermined value FEm, it is determined in step 708 that there is a medium. Thus, only when the values of FE1 and FE2 are larger than the predetermined value FEd, the absolute value of t11-t21 is smaller than the predetermined time tm, and the absolute value of FE1-FE2 is smaller than the predetermined value FEm. It is determined that there is a medium.
[0039]
Next, a mischucking detection method in an optical disc recording / reproducing apparatus equipped with a mechanical tilt sensor will be described.
When a mechanical tilt sensor is provided, the degree of disc tilt and the presence / absence of a disc can be determined by calculating a signal from this sensor. A sum signal and a difference signal are generated from the output of the mechanical tilt sensor. If both signals cannot be observed simultaneously due to the circuit configuration, the difference signal and the sum signal are calculated by using a switch. As a result, disc tilt, disc presence, and mischucking can be determined.
[0040]
Next, a method for discriminating DVD-type discs, particularly DVD-ROM 1 layer, DVD-ROM 2 layers, DVD-RAM, DVD-R, and DVD-RW will be described with reference to FIG.
FIG. 6 is a flowchart showing an embodiment of a processing operation for discriminating a part of a DVD type disc.
If the output terminal when the disc is determined to be a DVD disk in step 512 in FIG. 3 is A, the flow in FIG. First, in step 801, the sled is moved to place the optical pickup at a radius r = 23.7 mm of the disk. Next, in step 802, it is determined whether the DVD-type disc has one layer or two layers. For this purpose, the focus is swept and the number of S-shaped curves which are focus error signals is counted. When the recording surface is a single layer, two S hour curves are obtained: an S hour curve obtained from reflection on the disk surface and an S hour curve obtained from the disk recording surface. In the case of a two-layer disc, an S-shaped curve is obtained from the disc surface, the first recording surface, and the second recording surface, respectively. By counting this S-shaped focus error signal, 1 It can be discriminated whether it is a layer disc or a two-layer disc.
[0041]
If it is determined in step 802 that the disc is a double-layer disc, control data written in the lead-in of the disc is read in step 803. Since the disc type is described in this control data, when the disc type is described as a DVD-ROM double-layer disc, the process proceeds to step 804, where it can be discriminated as a DVD-ROM double-layer disc. it can. If the control data includes a DVD-ROM single layer disc in step 803, the S-curve count in step 802 is incorrect, so that it is determined as a DVD-ROM single layer disc as shown in step 805. .
[0042]
  If it is determined in step 802 that the disc is a DVD-type single-layer disc, the process proceeds to step 808, where a DVD other than R-DVD and DVD other than R is transferred.forElectric offset adjustmentRespectivelyIn step 809, an electric offset adjustment value other than DVD-R is set. For offset adjustment, for example, the servo circuit zero point adjustment and initial value adjustment can be performed on a DVD.−R and other DVD discs. Next, step810 and push-pull tracking hereerrorThe amplitude of the signal (referred to as PP signal) is acquired and stored. Then step811Then, the sled is moved and the optical pickup is adjusted so that the radius r of the disk is 25 mm. afterwards,In step 812Acquire and store the amplitude of the PP signal.
[0043]
  Next, the process proceeds to step 813, where the PP signal amplitude when r = 23.7 mm (referred to as pp23.7) and the PP signal amplitude when r = 25 mm (referred to as pp25) are compared. That is, the value of pp25 / pp23.7 is calculated. This is characterized in that the DVD-RAM has embossing and a small PP signal at a radius of 24.0 mm or less, and has a land / groove structure and a large PP signal at 24.0 mm or more. Since the PP signal is almost constant over the area, it is possible to distinguish these discs by comparing the amplitude of the PP signal before and after 24.0 mm.EasyTo do. In this embodiment, a discriminant of pp25 / pp23.7> pp_r1 is used. When pp25 / pp23.7 is larger than pp_r1, it is determined that the disc is a DVD-RAM. As described above, in the case of the RAM, pp25 / pp23.7 is sufficiently larger than 1, and when it is close to 1, it is determined as the other disk. In the present embodiment, when pp_r2 = 2 as a result of the examination, since the misjudgment is the smallest, the discrimination is made when pp25 / pp23.7 is greater than 2 or less than 2. Therefore, if pp25 / pp23.7 is larger than 2, it is determined as DVD-RAM in step 814, and the process proceeds to the steps shown in other drawings through the terminal B.
[0044]
When pp25 / pp23.7 is 1 or less, the process proceeds to step 815 to determine whether (pp25 + pp23.7)> pp_r2 is satisfied. pp_r2 is a predetermined constant and is stored in the memory of the optical disc apparatus. If (pp25 + pp23.7) is greater than the constant pp_r2, the possibility of DVD-R is high, so it is determined that the DVD-R is determined in step 816. Therefore, in step 817, the electric offset adjustment value for DVD-R is set. In step 818, the DVD-R is discriminated. After that, the terminal C is connected to the flowcharts of other drawings.
[0045]
  If (pp25 + pp23.7) is smaller than the constant pp_r2 in step 815, it is determined that there is a high possibility other than DVD-R, and the process proceeds to step 821, where the phase difference detection signal (DPD) which is a tracking error signalofGet the amplitude. Next, the process proceeds to step 822, where the amplitude of the DPD of r = 25 mm (referred to as dpd25) and pp25 (push-pull tracking of r = 25 mm).errorsignalofCheck (Amplitude). If the predetermined amplitude value of DPD is dpd_presence and the predetermined amplitude value of PP is pp_presence, if dpd25 <dpd_presence and pp25 <pp_presence are satisfied (in the case of Yes), DVD−Because there is a high possibility that it is an unrecorded disc of RW and + RW,In step 823, the DVD−RW and + RW are determined. However, DVD-ROM discs and recorded DVDs−Since RW and + RW discs may not satisfy the above determination (NO), the process proceeds to step 824, and an AGC (Automatic Gain Control) PE (Pull-in Error) gain in the analog RF front end is obtained. Look at the value of the setting register that sets. Since the PE gain is set so as to decrease the gain when the disc reflectivity is high, if the value of the gain setting register is smaller than a predetermined value in step 824, the possibility of DVD-ROM is determined in step 827. It is determined that there is, and the process proceeds to step 828. If the value is larger than the predetermined value, the reflectivity is low, so the DVD is displayed as shown in step 825.−There is a high possibility of RW and + RW.MistakeThere is also a possibility to recognize. Of these,Step823DVD−Possible RW, + RWRuAbout what was determinedTheIn step 829, the PP amplitude is adjusted to determine whether or not the adjustment has been completed. If it can be adjusted, the terminal DIn the figureConnected to the flowchart. If the amplitude cannot be adjusted (No) in step 829, the process proceeds to step 828.
[0046]
In step 828, it is checked again whether it is a single-layer disc or a double-layer disc. In the case of a double-layer disc, the control data is read in step 803 and discriminated as the DVD-ROM double layer in step 804 or the DVD-ROM single layer in step 805. Is done. If it is determined in step 828 that the disc is a single-layer disc, the control data is read in step 830, and based on the result, it is discriminated as the DVD-ROM 2 layer in step 804 or the DVD-ROM 1 layer in step 805.
[0047]
  Next, FIG.forA method for discriminating between DVD-R3.9, DVD-R4.7-A, and DVD-R4.7-G will be described. FIG. 7 is a flowchart showing an embodiment of a processing operation for discriminating other types of DVD-type discs. If it is determined that the DVD-R is determined in step 818 in FIG.CFrom step 901, LPP (land pre-pit) interpolation is performed, that is, the decrement is performed to read the LPP. In step 902, it is determined whether LPP data can be demodulated. If it can be demodulated (Yes), the possibility of an unrecorded disc is high, and it is determined in step 903 whether the block address of PART A before interpolation is F00000 or more. If the block address is smaller than F00000 in step 903, the process proceeds to step 904 to read the control data. If the LPP data cannot be demodulated in step 902, the S / N is bad or the possibility of a recorded disk is high. Therefore, in step 906, seek with the data ID is performed to optimize the servo signal. After setting PP signal, control in step 904dataIs read.
[0048]
  In step 903, if the block address of PART A before interpolation is F00000 or higher (Yes), the possibility of DVD-R4.7-G is high. In this case, in step 908, the presence / absence of RMD (Recording Management Data, which is a part of the recording part of DVD-R and DVD-RW) is checked.YeIf there is no RMD, ID1 to ID5 information is acquired from the LPP data in step 910, and control data is read in step 904. If there is RMD in step 908, the RMD is read in step 912, and in step 913, RPFI (R (RW) Physical FormatInformation is part of the recording data of DVD-R and DVD-RW. ) Is checked. If there is no RPFI in step 913, control data is read in step 904. If there is an RPFI in step 913,In step 914Read RPFI. If the RPFI can be read, it can be determined as DVD-R4.7-G as shown in step 916.
[0049]
  Read in step 914OnlyTakeRIf it is not possible, it is determined that the disc cannot be discriminated (not ready) as shown in step 918. In step 904, thisConAs a result of reading the trawl data, depending on the read disk type, step 92As shown in 0, it is discriminated as DVD-R3.9, as shown in Step 922, as discriminated as DVD-R4.7-A, or in Step 916.As shown inDiscriminated as DVD-R4.7-G,6 through terminal F.Step 805As shown inDiscriminated as DVD-RM1 layer or readOnlyTakeRIf not, step 918Of the disc as shown inIndistinguishable(Not ready)To be judged.
[0050]
Next, a method for distinguishing DVD-RAM1, DVD-RAM2, DVD-RW1.0, and DVD-RW1.1 will be described with reference to FIG.
FIG. 8 is a flowchart showing an embodiment of a processing operation for discriminating still another type of DVD-based disc. Step 814 in FIG. 6 is connected to terminal B. The terminal B is shifted to step 1101 in FIG. If it is determined in step 814 that the disc is a DVD-RAM, the control data is read in step 1101 and the disc type described therein is checked, so that the disc is discriminated as a DVD-RAM 1 as shown in step 1102. As shown in FIG.
[0051]
  FIG.NoAt step 823, it is discriminated as DVD-RW, + RW, and step 82 is executed.9If the PP amplitude can be adjusted, LPP data demodulation is performed through the terminal D in step 1104 of FIG. Since DVD + RW does not have LPP, it cannot be demodulated. In this case (in the case of No), the process proceeds to step 1106. First, the ID (address) in the data is looked for, seek to the current position, and after setting the DPD level, the control data is read in step 1108.
[0052]
  Since DVD-RW has LPP, it can be demodulated. In this case (Yes), in step 1110, the LPP is decremented and the LPP is read. ReadingOnlyTakeRIs impossibleIfIn other words, if the disc is already recorded,OnlyTakeRThere are things that cannot be done. Therefore, in this case, step 1112In order to read the physical information, seek is performed while looking at the ID (address) in the recorded data and the level of PP (push-pull servo signal) is set. In both cases of steps 1110 and 1112, the presence or absence of RMD is checked in step 1114. If there is no RMD, information of ID1 to ID5 of the disk is acquired in step 1116. As a result, in the case of -RW1.1, the process proceeds to step 1108 to read the control data. If -RW1.0 in step 1116, step 1124As shown in FIG.
[0053]
  In step 1114, if there is RMD, step 111 is performed.8Read RMD with step 1120Migrate toAndStep 1120Then, the presence / absence of RPFI is checked. If there is no RPFI, it is determined whether it is DVD-RW1.1 or DVD-RW1.0 based on the result of RMD. If it is -RW1.1, the control data is read in step 1108.Thus, in the case of -RW1.0, as shown in step 1124, it is determined as DVD-RW1.0.Step 1120If you have RPFI,In step 1122Read RPFI, step 1126As shown inDIt is determined as VD-RW1.1. Step 1108InBy reading the control data and looking at the disc type,Terminal G Through as shown in step 805 of FIG.DVD-ROM 1 layer,Or as shown in step 1126DVD-RW1.1,Or7 through terminal E.In step 918As shown, the disc cannot be identified (not ready)Is determined.
[0054]
As described above, according to the present invention, most CD discs and DVD discs can be discriminated. That is, it is possible to discriminate between a CD-type disc and a DVD-type disc, and a CD-type disc can discriminate between CD-RW, CD-R, and CD-ROM. .7, DVD-R4.7-G, DMD-ROM1 layer, DVD-ROM2 layer, DVD-RAM1, DVD-RAM2, DVD-RW1.0, and DVD-RW1.1.
Further, according to the present invention, disc mischucking or no disc is discriminated during the disc discriminating operation, and disc discrimination is performed only when the disc is normally chucked. A determination can be made.
[0055]
In particular, in the present invention, it is possible to discriminate between a single-layer disc and a multi-layer disc.
Further, it is determined whether chucking is normal or mischucking, and the disk determination is performed only when the chucking is normal. Therefore, the disk can be determined more accurately.
In the present invention, it is possible to discriminate DVD-RAM, DVD-R, and DVD-RW by obtaining tracking error signals at different disc radii for disc discrimination.
[0056]
【The invention's effect】
As described above, in the present invention, a single-layer disc and a multi-layer disc can be discriminated.
Further, by discriminating whether chucking is normal or mischucking and performing disc discrimination only when chucking is normal, discs can be discriminated more accurately.
Also, DVD-RAM, DVD-R, and DVD-RW can be discriminated by acquiring tracking error signals at different disk radii.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an embodiment of an optical disc recording / reproducing apparatus according to the present invention.
FIG. 2 is a flowchart showing a schematic processing operation of a disc discrimination method according to the present invention.
FIG. 3 is a flowchart for explaining an operation of discriminating between a CD-type optical disc and a DVD-type optical disc and a CD-type disc type discriminating process.
FIG. 4 is a diagram showing focus error signals detected on the inner and outer peripheral sides of the disc.
FIG. 5 is a flowchart showing an embodiment of a mischucking detection operation according to the present invention.
FIG. 6 is a flowchart showing an embodiment of a processing operation for discriminating a part of a DVD type disc.
FIG. 7 is a flowchart showing an embodiment of a processing operation for discriminating another part of the DVD type disc.
FIG. 8 is a flowchart showing an embodiment of a processing operation for discriminating still another type of DVD-based disc.
[Explanation of symbols]
  DESCRIPTION OF SYMBOLS 1 ... Optical disk, 2 ... Spindle motor, 3 ... Optical pick-up, 4 ... RF front end, 5 ...DigitalSignal processing circuit, 6 ... microcomputer.

Claims (16)

A step of determining that the disc is a DVD disc, a step of discriminating that the DVD disc is a single-layer disc, and obtaining a first push-pull tracking error signal at a first predetermined radius position of the disc. Obtaining a second push-pull tracking error signal at a second predetermined radius position that is greater than the first predetermined radius position; and wherein the amplitude of the second push-pull tracking error signal is the first push An optical disc discrimination method comprising: discriminating a DVD- RAM when the amplitude of the pull tracking error signal is larger. The optical disc discriminating method according to claim 1, reads the control data, the optical disc discriminating method comprising Rukoto comprising the step of determining whether DVD-RAM 2 or DVD-RAM 1 from the disk type of the control data. A step of determining that the disc is a DVD disc, a step of discriminating that the DVD disc is a single-layer disc, and obtaining a first push-pull tracking error signal at a first predetermined radius position of the disc. step a, the amplitude of the first predetermined radial position greater than the second acquiring a second push-pull tracking error signal at a predetermined radial position, said first and second push-pull tracking error signal of the disc step a, the optical disc discriminating method in which the result of the operation, characterized in that it comprises a step of determining that DVD-R disc is greater than a predetermined value for calculating the sum of. The optical disc discriminating method according to claim 3, reads control data, DVD-R3.9 or from the disk type of the control data, or DVDR4.7-A, comprising the step of determining whether DVDR4.7-G An optical disc discrimination method characterized by the above. A step of determining that the disc is a DVD disc, a step of discriminating that the DVD disc is a single-layer disc, and obtaining a first push-pull tracking error signal at a first predetermined radius position of the disc. step a, the amplitude of the first predetermined radial position greater than the second acquiring a second push-pull tracking error signal at a predetermined radial position, said first and second push-pull tracking error signal of the disc If the sum of is determined to a predetermined value smaller than obtaining a tracking error signal of the phase difference method in a predetermined position of the disk, the amplitude of the second push-pull tracking error signal is smaller than a predetermined value, In addition, when the amplitude of the tracking error signal of the phase difference method is smaller than a predetermined value , DVD- RW, + RW And a step of discriminating the optical disc. 6. The optical disc discrimination method according to claim 5, wherein when discriminating between DVD-RW1.1 and DVD-RW1.0, if there is RPFI, discrimination is performed based on RPFI data, and there is no RPFI and there is RMD. optical disc discriminating method performs determination by RMD data when RMD is not characterized by Rukoto comprising the step of performing determination on the data of LPP. A step of determining that the disc is a DVD disc, a step of discriminating that the DVD disc is a single-layer disc, and obtaining a first push-pull tracking error signal at a first predetermined radius position of the disc. step a, the amplitude of the first predetermined radial position greater than the second acquiring a second push-pull tracking error signal at a predetermined radial position, said first and second push-pull tracking error signal of the disc If the sum of is determined to a predetermined value smaller than obtaining a tracking error signal of the phase difference method in a predetermined position of the disk, the amplitude of the second push-pull tracking error signal be greater than a predetermined value and phase difference method DVD when the amplitude of the tracking error signal Ru Ah or more predetermined value -ROM, or An optical disc discrimination method comprising the step of discriminating from a DVD-RW. The optical disc discriminating method according to claim 7, reads control data, said control DVD-ROM or from the disk type data, DVD - RW1.1 optical disc discriminating method comprising Rukoto comprising the step of determining whether. Means for discriminating that the mounted optical disc is a DVD disc; means for discriminating that the DVD disc is a single layer disc; and a first push-pull tracking at a first predetermined radius position of the optical disc. Gets the amplitude of the error signal, means for acquiring the amplitude of the second push-pull tracking error signal at a predetermined radial position greater than a second predetermined radial position of the first, the second push-pull tracking error signal An optical disc apparatus comprising: means for discriminating a DVD- RAM when the amplitude is larger than the amplitude of the first push-pull tracking error signal. The optical disk apparatus according to claim 9, it reads the control data, the optical disk apparatus according to claim Rukoto comprising means for determining whether DVD-RAM 2 or DVD-RAM 1 from the disk type of the control data. Means for discriminating that the mounted optical disc is a DVD disc; means for discriminating that the DVD disc is a single layer disc; and a first push-pull tracking at a first predetermined radius position of the optical disc. Means for obtaining an error signal, means for obtaining a second push-pull tracking error signal at a second predetermined radius position larger than the first predetermined radius position of the optical disc, and the first and second push-pull An optical disc apparatus comprising: means for calculating a sum of amplitudes of tracking error signals , and discriminating a DVD-R disc when a result of the calculation is larger than a predetermined value . The optical disk apparatus according to claim 11, reads the control data, DVD-R3.9 or from the disk type of the control data, or DVDR4.7-A, Ru comprises means for determining whether DVDR4.7-G An optical disc device characterized by the above. Means for discriminating that the mounted optical disc is a DVD disc; means for discriminating that the DVD disc is a single layer disc; and a first push-pull tracking at a first predetermined radius position of the optical disc. Means for obtaining an error signal amplitude and obtaining an amplitude of a second push-pull tracking error signal at a second predetermined radius position larger than the first predetermined radius position of the optical disc; and the first and second pushes Means for obtaining a phase difference tracking error signal at a predetermined position of the disk when it is determined that the sum of the amplitudes of the pull tracking error signal is smaller than a predetermined value ; and the amplitude of the second push-pull tracking error signal DVD -RW but smaller than a predetermined value, and the amplitude of the tracking error signal of the phase difference method when a predetermined value smaller than , And + RW discriminating means. 14. In the optical disc apparatus according to claim 13, when there is RPFI when discriminating between DVD-RW1.1 and DVD-RW1.0, discrimination is performed based on RPFI data, and when there is no RPFI and there is RMD. performs determination by RMD data optical disk apparatus according to claim Rukoto comprises means for discriminating the data of the LPP when RMD no. Means for discriminating that the mounted optical disc is a DVD disc; means for discriminating that the DVD disc is a single layer disc; and a first push-pull tracking at a first predetermined radius position of the disc. Means for obtaining an error signal; means for obtaining a second push-pull tracking error signal at a second predetermined radius position greater than the first predetermined radius position of the disk; and the first and second push-pull tracking. When it is determined that the sum of the amplitudes of the error signals is smaller than a predetermined value, a means for acquiring a phase difference tracking error signal at a predetermined position of the disk, and the amplitude of the second push-pull tracking error signal is predetermined. when the value or more, and the phase difference method of the DVD when the amplitude of the tracking error signal is equal to or higher than a predetermined value -ROM, or An optical disc apparatus comprising: a DVD-RW discriminating unit . The optical disk apparatus according to claim 15, reads the control data, DVD-ROM or from the disk type of the control data, the optical disk apparatus according to claim Rukoto comprising means for determining whether DVD-RW1.1.

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